Universe_The Definitive Visual Guide

smithsonian

UNIVERSE

smithsonian

UNIVERSE General Editor

Martin Rees

SENIOR EDITOR

Peter Frances

SENIOR ART EDITORS

Mabel Chan, Spencer Holbrook, Peter Laws

PROJECT EDITORS

Georgina Garner, Rob Houston, Gill Pitts, Martyn Page, David Summers, Miezan van Zyl

PROJECT ART EDITORS

Dave Ball, Sunita Gahir, Alison Gardner, Mark Lloyd, Duncan Turner

EDITORS

Joanna Chisholm, Ben Hoare, Giles Sparrow

DESIGNERS

Kenny Grant, Jerry Udall

US SENIOR EDITOR

DESIGN ASSISTANT

Rebecca Warren

Marilou Prokopiou

US EDITORS

Jill Hamilton, Christine Heilman PROOF READERS

Steve Setford, Jane Simmonds, Nikky Twyman

PICTURE RESEARCHER

Louise Thomas INDEXERS

Hilary Bird, Jane Parker

ILLUSTRATORS Anbits, Combustion Design and Advertising, Fanatic Design, JP Map

Graphics, Moonrunner Design, Pikaia Imaging, Planetary Visions, Precision Illustration PRODUCTION CONTROLLERS Heather Hughes, Mary Slater PRODUCTION EDITORS John Goldsmid, Adam Stoneham MANAGING EDITOR Camilla Hallinan MANAGING ART EDITOR Michelle Baxter PUBLISHER Sarah Larter ART DIRECTORS Philip Ormerod, Bryn Walls ASSOCIATE PUBLISHING DIRECTOR Liz Wheeler PUBLISHING DIRECTOR Jonathan Metcalf CONSULTANT FOR REVISED EDITION

Andrew K. Johnston, Center for Earth and Planetary Studies, National Air and Space Museum, Smithsonian Institution, USA. First American edition, 2005 This revised edition published in 2012 Published by DK Publishing, 375 Hudson Street, New York, New York, 10014 12 13 14 10 9 8 7 6 5 4 3 2 1 001 – 184784 – Oct/2012 Copyright © 2005, 2012 Dorling Kindersley Limited All rights reserved. Without limiting the rights under copyright reserved above, no part of this publication may be reproduced, stored in or introduced into a retrieval system, or transmitted, in any form, or by any means (electronic, mechanical, photocopying, recording, or otherwise), without the prior written permission of both the copyright owner and the above publisher of this book. Published in Great Britain by Dorling Kindersley Limited. A catalog record for this book is available from the Library of Congress. ISBN 978-0-7566-9841-6 DK books are available at special discounts when purchased in bulk for sales promotions, premiums, fund-raising, or educational use. For details contact: DK Publishing Special Markets, 375 Hudson Street, New York, 10014 or [email protected]. Color reproduction by GRB Editrice, s.r.l., Italy Printed by Leo Paper Products, China

Discover more at www.dk.com Jacket the Fox Fur Nebula; Endpapers the Orion Nebula; Half-title page the Helix Nebula; Title page Jupiter’s moon Europa; Contents page the Eagle Nebula

CONTENTS

LONDON, NEW YORK, MELBOURNE, MUNICH, AND DELHI

ABOUT THIS BOOK

6

A SHORT TOUR OF THE UNIVERSE

8

BY MARTIN REES

INTRODUCTION

WHAT IS THE UNIVERSE?

20

THE SCALE OF THE UNIVERSE

22

CELESTIAL OBJECTS

24

MATTER

28

RADIATION

34

GRAVITY, MOTION, AND ORBITS

38

SPACE AND TIME

40

EXPANDING SPACE

44

THE BEGINNING AND END OF THE UNIVERSE

46

THE BIG BANG

48

OUT OF THE DARKNESS

54

LIFE IN THE UNIVERSE

56

THE FATE OF THE UNIVERSE

58

THE VIEW FROM EARTH

60

THE CELESTIAL SPHERE

62

CELESTIAL CYCLES

64

PLANETARY MOTION

68

STAR MOTION AND PATTERNS

70

LIGHTS IN THE SKY

74

NAKED-EYE ASTRONOMY

76

BINOCULAR ASTRONOMY

80

TELESCOPE ASTRONOMY

82

SETTING UP A TELESCOPE

86

THE MILKY WAY

226

USING THE SKY GUIDES

428

ASTROPHOTOGRAPHY

88

STARS

232

JANUARY

430

ASTRONOMICAL OBSERVATORIES

90

THE LIFE CYCLES OF STARS

234

FEBRUARY

436

OBSERVING FROM SPACE

94

STAR FORMATION

238

MARCH

442

MAIN-SEQUENCE STARS

250

APRIL

448

OLD STARS

254

MAY

454

STELLAR END POINTS

266

JUNE

460

MULTIPLE STARS

274

JULY

466

VARIABLE STARS

282

AUGUST

472

STAR CLUSTERS

288

SEPTEMBER

478

EXTRA-SOLAR PLANETS

296

OCTOBER

484

NOVEMBER

490

DECEMBER

496

GUIDE TO THE UNIVERSE THE SOLAR SYSTEM

98

THE HISTORY OF THE SOLAR SYSTEM

100

THE FAMILY OF THE SUN

102

THE SUN

104

MERCURY

110

VENUS

114

EARTH

124

THE MOON

136

MARS

150

ASTEROIDS

170

JUPITER

178

SATURN

188

URANUS

200

NEPTUNE

204

224

BEYOND THE MIKY WAY

300

TYPES OF GALAXY

302

GALAXY EVOLUTION

306

ACTIVE GALAXIES

320

GALAXY CLUSTERS

326

GALAXY SUPERCLUSTERS

336

THE NIGHT SKY THE CONSTELLATIONS

344

THE HISTORY

THE KUIPER BELT AND THE OORT CLOUD

THE MILKY WAY

208

OF CONSTELLATIONS

346

COMETS

212

MAPPING THE SKY

348

METEORS AND METEORITES

220

Guide to the Constellations

354

MONTHLY SKY GUIDE

426

GLOSSARY

502

INDEX

510

ACKNOWLEDGMENTS

526

ABOUT THIS BOOK

ABOUT THIS BOOK

GUIDE TO THE UNIVERSE This part of the book focuses on specific regions of space, starting from the Sun and then moving outward to progressively more distant reaches of the universe. It is divided into three sections, covering the solar system, the Milky Way, and features beyond the Milky Way. In each section, introductory pages describe features in a general way and explain the processes behind their formation. These pages are often followed by detailed profiles of actual features (such as individual stars), usually arranged in order of their distance from Earth.

Universe is divided into three main sections. The INTRODUCTION is an overview of the basic concepts of astronomy. GUIDE TO THE UNIVERSE looks, in turn, at the solar system, the Milky Way (our home galaxy), and the regions of space that lie beyond. Finally, THE NIGHT SKY is a guide to the sky for the amateur skywatcher.

150

MARS

MARS

MARS

INTRODUCTION

38–39 Gravity, motion, and orbits 64–65 Celestial cycles 68–69 Planetary motion 100–101 The history of the Solar System

This section is about the universe and astronomy as a whole. It is subdivided into three parts. what is the universe? looks at different kinds of objects in the universe and the forces governing how they behave and interact. the beginning and end of the universe covers the origin and history of the universe, while the view from earth explains what we see when we look at the sky.

102–103 The family of the Sun

MARS IS THE OUTERMOST of the four rocky planets. Also known as the Red Planet because of its rust-red color, it is named after the Roman god of war. Its varied surface features include deep canyons and the highest volcanoes in the solar system. Although Mars is now a dry planet, a large body of evidence indicates that liquid water once flowed across its surface.

AVERAGE DISTANCE FROM THE SUN

WHAT IS THE UNIVERSE?

MATTER

ORBIT Mars has an elliptical orbit, so at its closest direction approach to the Sun (perihelion) it receives of sunlight 45 percent more solar radiation than at the farthest point (aphelion). This means that the south polar region surface temperature can vary from -195˚F exposed to (-125˚C) at the winter pole, to 77˚F (25˚C) sunlight is ice-free during the summer. At 25.2˚, the current axial tilt of Mars is similar to that of Earth and, like Earth, Mars experiences changes in seasons as equator receives more the north pole, and then the south pole, points sunlight than toward the Sun during the course of its orbit. at 60° tilt Throughout its history, Mars’s axial tilt has fluctuated greatly due to various factors, including Jupiter’s gravitational pull. These fluctuations have caused significant changes in climate. When Mars is heavily tilted, the poles are more exposed to the Sun, causing water CHANGES IN AXIAL TILT ice-free ice to vaporize and Water-ice distribution during a equator Martian winter in the northern build up around the hemisphere varies with the axial colder lower latitudes. tilt. The translucent white areas At a lesser tilt, water ice shown here represent thin ice that becomes concentrated melts during the summer, whereas the thick white ice remains. at the colder poles. NORTHERN SPRING EQUINOX

EXAMINED AT THE TINIEST SCALE,

60°

The Big Bang 48–51 Out of the darkness 54–55 The Sun 104–07

WHAT IS MATTER?

STRUCTURE OF A CARBON ATOM

At the center of an atom is the nucleus, which contains protons and neutrons. Electrons move around within two regions, called shells, surrounding the nucleus. The shells appear fuzzy because electrons do not move in defined paths.

OUTER ELECTRON SHELL

Region in which four electrons orbit

Matter is anything that possesses mass—that is, anything affected by gravity. Most matter on Earth is made of atoms and ions. Elsewhere in the universe, however, matter exists under a vast range of conditions and takes a variety of forms, from thin interstellar medium (see p.228) to the matter in infinitely dense black holes (see p.267). Not all of this matter is made of atoms, but all matter is made of some kind of particle. Certain types of particle are fundamental—that is, they are not made of smaller sub-units. The most common particles within ordinary matter are quarks and electrons, which make up atoms and ions and form all visible matter. Most of the universe’s matter, however, is not ordinary matter, but dark matter (see p.27), LUMINOUS MATTER perhaps composed partly of These illuminated gas clouds neutrinos, theoretical WIMPs in interstellar space are (weakly interacting massive made of ordinary matter, composed of atoms and ions. particles), or both.

INNER ELECTRON SHELL

Region within which two electrons orbit

CHEMICAL ELEMENTS

IMAGING THE ATOM

A colorless gas at 70°F (21°C). Its atoms have just 1 proton and 1 electron in a single shell.

incoming photon

Elements vary markedly in their properties, as shown by the four examples here. These properties are determined by the elements’ different atomic structures.

The electrons in atoms can exist in different energy states. By moving between energy states, they can either absorb or emit packets, or quanta, of energy. These energy packets are called photons.

nucleus nucleus EMISSION

electron falls back to lower energy state

ABSORPTION

electron at high energy state

I NT ROD UCT I ON

ELECTRON

empty shell

Electrons have a negative charge and a mass more than a thousand times smaller than a proton or neutron

blue quark

ION (CHARGE +1)

electron in outer shell

INSIDE A NEUTRON

Protons and neutrons are each made of three quarks, bound by gluons. The quarks flip between “red,” “green,” and “blue” forms, but there is always one of each color.

IONIZATION

One way an atom may become a positive ion is by the electron’s absorbing energy from a high-energy photon and, as a result, being ejected, along with its charge, from the atom.

ATOM (NEUTRAL, NO CHARGE)

proton

SULFUR

BROMINE

A yellow, brittle solid at 70°F (21°C). Its atoms have 16 protons, 16–18 neutrons, and 16 electrons in 3 shells.

A fuming brown liquid at 70°F (21°C). Its atoms have 35 protons, 44 or 46 neutrons, and 35 electrons in 4 shells.

Mars has a very thin atmosphere, which exerts an average pressure on the surface of about 6 millibars (0.6 percent of the atmospheric pressure on Earth). The atmosphere is mostly carbon dioxide, and it appears pink because fine particles of iron oxide dust are SAND DUNES suspended in it. Thin clouds of Looking down into a small impact crater frozen carbon dioxide and water in a southern upland area called Noachis Terra, NASA’s Mars Reconnaissance Orbiter ice are present at high altitudes, captured these rippling sand dunes. The and clouds also form on high dunes were sculpted by Martian winds and peaks in the summer. Mars is a are shown here in enhanced color. The image is about 0.6 miles (1 km) across. cold, dry planet—the average surface temperature is -81°F (-63°C)—where it never rains, but in the winter clouds at the polar regions cause ground frosts. Mars has highly dynamic weather systems. In the southern spring and summer, warmer winds from the south blow into the northern hemisphere, stirring up local clouds of dust that can reach 3,000 ft (1,000 m) in height and last for weeks. The high-level winds can also create powerful dust storms that cover vast areas of the planet (see below). Mars also has low-level prevailing winds, which have sandblasted its surface for centuries, creating distinctive landforms (see photograph, above).

water ice builds up at colder north pole

35° water ice concentrated around north polar region

25°

NORTHERN WINTER SOLSTICE

neutron

proton

chloride ion

Most matter in the universe consists of unbound atoms or ions of a few chemical elements, but a significant amount exists as compounds, containing atoms of more than one element joined by chemical bonds. Compounds occur in objects such as planets and asteroids, in living organisms, and in the interstellar medium. In ionic compounds, such as salts, atoms trade electrons, and the resulting charged ions are bonded by electrical forces, and arranged in a IONIC COMPOUND rigid, crystalline structure. In covalent Compounds of this compounds, such as water, the atoms are type consist of the held in structures called molecules by the ions of two or more chemical elements, sharing of electrons between them. Two typically arranged in a or more identical atoms can also combine repeating solid structure. This example is salt, sodium chloride. to form molecules of certain elements.

This section begins by looking at some basic questions about the size and shape of the universe. It goes on to explain concepts such as matter and radiation, the motion of objects in space, and the relationship between time and space. 48

THE BEGINNING AND END OF THE UNIVERSE

THE BIG BANG

THE BIG BANG are all thought to have come 28–31 Matter into existence 13.7 billion years ago, in the event called the Big 34–37 Radiation Bang. In its first moments, the universe was infinitely dense, 44–45 Expanding space unimaginably hot, and contained pure energy. But within a tiny The fate of the Universe 58–59 fraction of a second, vast numbers of fundamental Mapping deep space 339 particles had appeared, created out of energy as the universe cooled. Within a few hundred thousand years, these particles had combined to form the first atoms.

RECREATING THE EARLY UNIVERSE At the European Centre for Nuclear Research, also known as CERN, particle physicists are unraveling the finer details of the early universe by smashing particles together in particle accelerators and searching for traces of other fundamental particles. In doing so, they explore the constituents of matter and the forces that control their interactions. CERN scientists have even recreated conditions like those shortly after the Big Bang, by creating plasmas containing free quarks and gluons.

IN THE BEGINNING

A ten-trillionth 10 –43 seconds

of a yoctosecond

quark

quark

quark

106m (620 miles/1,000 km)

109m (620,000 miles/1 million km)

billion trillion °C) 1021K (1.8 billion trillion °F/1 billion trillion °C)

rce rfo

1 nanosecond 10 –9 seconds

SEPARATION OF THE ELECTROWEAK FORCE

1 picosecond 10 –12 seconds

1 microsecond 10 –6 seconds

antiquark

FREEZE OUT AND ANNIHILATION Higgs boson (hypothetical)

Particle–antiparticle pairs, including quarks– antiquarks, were still constantly forming and returning to energy. For each type of particle, the temperature would eventually drop to the point where the particles “froze out”—they could no longer form from the background pool of energy. Most free particles and antiparticles of each type were rapidly annihilated, leaving a small residue of particles. As quarks and antiquarks froze out at the end of the quark era, instead of being annihilated, some began grouping to form heavier particles.

photon

antineutrino

quark–antiquark forming and annihilating

weak nuclear force

QUARKS BECOMING BOUND INTO HEAVIER PARTICLES BY GLUONS

su

pe

1015K (1,800 trillion °F/1,000 trillion °C)

1 femtosecond 10 –15 seconds

1 attosecond 10 –18 seconds

X-boson

electroweak force

1012m (620 million miles/1 billion km)

1018K (1.8 million trillion °F/1 million trillion °C)

Near the end of the quark era, the electroweak force separated into the electromagnetic force and the weak interaction (see p.30). From then on, the forces of nature and physical laws were as they are now experienced. 1 zeptosecond 10 –21 seconds

strong nuclear force

electromagnetic force

gravitational force

10–43 SECONDS

Higgs boson (hypothetical)

–12 10–36 SECONDS 10 SECONDS

INTRODU CTION

VERY SMOOTH

EXTREMELY SMOOTH AND FLAT

THE VIEW FROM EARTH

FOR CENTURIES, humans have known that stars lie at different distances from Earth. However, when recording the positions of stars in the sky, it is convenient to north celestial lies pretend that they are all stuck to the inside of pole directly above Earth’s North a sphere that surrounds Earth. The idea of this Pole sphere also helps astronomers to understand how their location on Earth, the time of night, and the time of year affect what they see in the night sky.

The celestial sphere is purely imaginary, with a specific shape but no precise size. Astronomers use exactly defined points and curves on its surface as references for describing or determining the positions of stars and other celestial objects.

line perpendicular to ecliptic plane (plane of Earth’s orbit around Sun)

Earth’s axis is tilted at 23.5°

celestial sphere

YEARLY SKY MOVEMENTS

Earth

As Earth orbits the Sun, the Sun seems to move against the background of stars. As the Sun moves into a region of the sky, its glare washes out fainter light from that part, so any star or other object there temporarily becomes difficult to view from anywhere on Earth. Earth’s orbit also means that the part of the celestial sphere on the opposite side to Earth from the Sun—that is, the part visible in the middle of the night— changes. The visible part of the sky at, for example, midnight in June, September, December, and March is significantly different—at least for observers at equatorial or Sun mid-latitudes on Earth.

Earth’s equator

Earth at Northern Hemisphere’s winter solstice (December 21/22)

Sun’s motion

EFFECTS OF LATITUDE

autumnal equinox (first point of Libra), one of two points of intersection between celestial equator and ecliptic south celestial pole lies below Earth’s South Pole

north celestial pole

MOTION AT NORTH POLE

W

north celestial pole S E

Earth

N circumpolar area

stars never visible

For a person on the equator, Earth’s rotation brings all parts of the celestial sphere into view for some time each day. The celestial poles are on the horizon.

OBSERVER AT NORTH POLE

For this observer, the northern half of the celestial sphere is always visible, and the southern half is never visible. The celestial equator is on the observer’s horizon.

OBSERVER AT MID-LATITUDE

N

N

At the equator, stars and other celestial objects appear to rise vertically in the east, move overhead, and then fall vertically and set in the west.

For this observer, a part of the celestial sphere is always visible, a part is never visible, and Earth’s rotation brings other parts into view for some of the time each day.

W

S E

stars sometimes visible

MOTION AT EQUATOR

position of observer observer’s horizon

MOTION AT MID-LATITUDE

W S

Earth at Northern Hemisphere’s summer solstice (June 21)

At opposite points of Earth’s orbit, an observer on the equator sees exactly opposite halves of the celestial sphere at midnight.

Earth’s axis of rotation

Earth’s orbit

hemisphere visible from equator at midnight on the summer solstice

pre-dawn glow obscures stars

observer’s view after sunset is obscured in the west by the Sun

North Pole, around which Earth rotates

Earth’s rotation

6:00 AM

zenith at dawn

observer’s view before sunrise is obscured in the east by the Sun

EXPLORING SPACE

ARISTOTLE’S SPHERES sphere of Until the 17th century ad, the idea of a “fixed” celestial sphere surrounding Earth stars was not just a convenient fiction— many people believed it had a physical reality. Such beliefs date back to a model of the universe developed by the Greek philosopher Aristotle (384–322 bc) and elaborated by the astronomer Ptolemy (ad 85–165). Aristotle placed Earth stationary at the universe’s center, surrounded by several transparent, concentric spheres to which the stars, planets, Sun, and Moon were attached. Ptolemy supposed that the spheres ARISTOTELIAN MODEL OF THE UNIVERSE rotated at different speeds around Stars are fixed to the outer sphere. Working inward, Earth, so producing the observed the other spheres around Earth carry Saturn, Jupiter, motions of the celestial bodies. Mars, the Sun, Venus, Mercury, and the Moon.

north celestial pole

celestial meridian—the line of 0° right ascension

angle of declination (45°), above celestial equator

star position

CELESTIAL COORDINATES Using the celestial sphere concept, astronomers can record and find the positions of stars and other celestial objects. To define an object’s position, astronomers use a system of coordinates, similar to latitude and longitude on Earth. The coordinates are called declination and right ascension. Declination is measured in degrees and arc-minutes (60 arc-minutes = 1 degree/1°) north or south of the celestial equator, so it is equivalent to latitude. Right ascension, the equivalent of longitude, is the angle of an object to the east of the celestial meridian. The meridian is a line passing through both celestial poles and a point on RECORDING A STAR’S POSITION the celestial equator called the first point of Aries or The measurement of a star’s position vernal equinox point (see p.65). An object’s right on the celestial sphere is shown here. ascension can be stated in degrees and arc-minutes This star has a declination of about 45° or in hours and minutes. One hour is equivalent to (sometimes written +45°) and a right 15°, because 24 hours make a whole circle. ascension of about 1 hour, or 15°.

45°

celestial equator

first point of Aries (vernal equinox point) is the origin for right-ascension measurements

angle of right ascension (1 hour, or 15°)

INT RO D UC TIO N

stars always visible

At the poles, all celestial objects seem to circle the celestial pole, directly overhead. The motion is counterclockwise at the North Pole, clockwise at the south. At mid-latitudes, most stars rise in the east, cross the sky obliquely, and set in the west. Some (circumpolar) objects never rise or set but circle the celestial pole.

KEY

hemisphere visible from equator at midnight on the winter solstice

JUNE AND DECEMBER SKIES

MIDNIGHT

zenith at midnight observer’s view at midnight is unobscured

One of the particles thought to have existed during the early moments of the Big Bang was a very-high-mass particle, the X-boson (along with its own antiparticle, the anti-Xboson). The X-boson and its antiparticle were unstable and decayed into other particles and antiparticles—quarks, antiquarks, electrons, and positrons (antielectrons). A peculiarity of the X-boson and its antiparticle is that, when they decayed, they produced a tiny preponderance of particles over antiparticles— that is, about a billion and one particles to each billion antiparticles. When these were later annihilated, a residue of particles remained, and it is postulated that these gave rise to all the matter currently in the universe.

decaying X-boson

quark–antiquark pair

X-boson decay products (particles and antiparticles)

STRUCTURE Mars is a small planet, about half the size of Earth, and farther away from the Sun. Its size and distance mean that it has cooled more rapidly than Earth, and its once-molten iron core is probably now solid. Its relatively low density compared to the other terrestrial planets indicates that the core may also contain a lighter element, such as sulfur, in the form of iron sulfide. The small core is surrounded by a thick mantle, composed of solid silicate rock. The mantle was a source of volcanic activity in the past, but it is now inert. Data gathered by the Mars Global Surveyor spacecraft has revealed that the rocky crust is about 50 miles (80 km) thick in the southern hemisphere, whereas it is only about 22 miles (35 km) thick in the northern hemisphere. Mars has the same total land area as Earth, since it has no liquid water on its surface.

small, probably solid iron core

EVOLUTION OF A STORM SYSTEM

mantle of silicate rock

SCARRED SURFACE

This mosaic of Viking Orbiter images shows Mars’s distinct red coloration and reveals the vast extent of the Valles Marineris, a system of valleys more than 2,500 miles (4,000 km) long.

MARS INTERIOR

Mars has a distinct crust, mantle, and core. The core is much smaller in proportion to Earth’s, and has probably solidified.

rock crust

On June 30, 1999, a storm system developed over the north polar region of Mars.

1

A giant, turbulent cloud of orange-brown dust was raised by high surface winds.

2

Expanding rapidly, the storm swirled over the white ice cap (center, top).

3

Six hours after the first image was taken, the storm was still gathering strength.

4

artwork of planet’s interior structure

238

main image shows planet as it appears from space

illustrations show atmospheric composition for each planet

STAR FORMATION

STAR FORMATION

TRIGGERS TO STAR FORMATION

STARS ARE FORMED by the gravitational collapse of cool, dense interstellar clouds. These clouds are composed mainly of molecular hydrogen (see p.228). A cloud has to be of a 228 The interstellar medium certain mass for gravitational collapse to occur, and a trigger 232–33 Stars is needed for the collapse to start, since the clouds are held 234–37 The life cycles of stars up by their own internal pressure. Larger clouds fragment as Star clusters 288–89 they collapse, forming sibling protostars that initially lie close together—some so close they are gravitationally bound. The material heats up as it collapses until, in some clouds, the temperature and pressure at their centers become so great that nuclear fusion begins and a star is born.

Clouds of interstellar material need a trigger to start them collapsing, since they are held up by their own pressure and that of internal magnetic fields. Such a trigger might be as simple as the gravitational tug from a passing star, or it might be a shock wave caused by the blast from a supernova or the collision of two or more galaxies. In spiral galaxies such as the Milky Way, density waves move through the dust and gas in the galactic disk (see p.227). As the waves pass, they temporarily increase the local density of interstellar material, causing it to collapse. Once the waves have passed, their shape can be picked out by the trails of bright young stars.

24–27 Celestial objects 55 The first stars

STAR-FORMING REGION

In the nebula RCW 120, in the southern Milky Way, an expanding bubble of ionized gas is causing the surrounding material to collapse into dense clumps, in which new stars will be born.

STELLAR NURSERIES As well as being among the most beautiful objects in the universe, star-forming nebulae contain a combination of raw materials that makes star birth possible. These clouds of hydrogen molecules, helium, and dust can be massive systems, hundreds of light-years across or smaller individual clouds, known as Bok globules. Although they may lie undisturbed for millions of years, disturbances can trigger these nebulae to collapse and fragment into smaller clouds from which stars are formed. Remnants from the star-forming nebulae will surround the stars, and the stellar winds produced by the new stars can, in turn, cause these remnants to collapse. If the clouds are part of a larger complex, this can become a great stellar nursery. Massive stars have relatively short lives, and they can be born, live, and die as a supernova while their less-massive siblings are still forming. The shock wave from the supernova FORMATION IN ACTION may plow through nearby interstellar Within the nebula NGC 2467 lie stars matter, triggering yet more star birth. at various stages of formation. At the

color-coded panel contains references to other relevant sections

lower left lies a very young star that is breaking free of its surrounding birth cocoon of gas. On the far right, a wall of bright gas glows as it is evaporated by the energy of many newly formed hot stars. Dark lanes of dust at the center hide parts of the nebula that are probably forming new stars.

GALA

A ring galax have forma

FROM

Shock super the in new s

ST

BOK GLOBULE

Small, cool clouds of dust and gas, known as Bok globules, are the origins of some of the Milky Way’s lower-mass stars.

Wh clou neig tran pair usua stars (see dust

star-forming region

Bok globule young star clusters

VIOLE

Young formi 1427A with which result stunn

stellar EGGS

STELLAR EGGS

Within the evaporating gaseous globules (EGGS) of the Eagle Nebula, interstellar material is collapsing to form stars.

TO

As c cont they beca form thei

E

△ THE VIEW FROM EARTH

This section presents a simple model for making sense of the changing appearance of the sky. It also contains practical advice on looking at the sky with the naked eye, telescopes, and binoculars.

The subject of this section is the Milky Way and the stars, nebulae, and planets that it contains. Pages such as those shown here describe how particular types of features are formed.

J.L.E. DREYER

Danish–Irish astronomer Joh Louis Emil Dreyer (1852–19 compiled the New General Catalog of Nebulae and Clu of Stars, from which nebulae galaxies get their NGC num the time of compilation, it w known if all the nebulous ob were within the Milky Way. studied the proper motions of many and concluded the “spiral nebulae,” now known to be spiral galaxies, were likely to be more distant objects.

quark

antiquark

particles and antiparticles meet, converting their combined matter into pure energy (photons)

slight excess of particles left over

quark and antiquark forming from energy, and immediately returning to energy as they meet

△ THE BEGINNING AND END OF THE UNIVERSE

The universe is thought to have originated in an event known as the Big Bang. This section describes the Big Bang in detail and looks at how the universe came to be the way it is now, as well as how it might end.

afterglow from sunset obscures stars

CIRCUMPOLAR STARS

Stars in the polar regions of the celestial sphere describe perfect partcircles around the north or south celestial pole during one night, as shown by this longexposure photograph.

Earth’s North Pole

Earth’s spin

An observer on Earth can view, at best, only half of the celestial sphere at any instant (assuming a cloudless sky and unobstructed horizon). The other half is obscured by Earth’s bulk. In fact, for an observer at either of Earth’s poles, a specific half of the celestial sphere is always overhead, while the other half is never visible. For observers at other latitudes, Earth’s rotation continually brings new parts of the celestial sphere into view and hides others. This means, for example, that over the course of a night, an observer at a latitude of 60°N or 60°S can see up to three-quarters of the celestial sphere for at least some of the time; and an observer at the equator can see every point on the celestial sphere at some time.

celestial equator

As the Earth spins, all celestial objects move across the sky, although the movements of the stars and planets become visible only at night. For an observer in mid-latitudes, stars in polar regions of the celestial sphere describe a daily circle around the north or south celestial pole. The Sun, Moon, planets, and the remaining stars rise along the eastern horizon, sweep in an arc across the sky, and set in the west. This motion has a tilt to the south (for observers in the Nothern Hemisphere) or to the north (Southern Hemisphere)— the lower the observer’s latitude, the steeper the tilt. Stars have fixed positions on the sphere, so the pattern of their movement EQUATORIAL NIGHT zenith at repeats with great precision once 6:00 PM From the equator, almost the sunset every sidereal day (see p.66). The whole of the celestial sphere can be seen for some of the planets, Sun, and Moon always move time during one night. The on the celestial sphere, so the Sun’s glow obscures only a period of repetition differs from small part of the sphere. that of the stars.

stars are fixed to the sphere’s surface and appear to move in opposite direction of Earth’s spin

vernal or spring equinox (first point of Aries)

63

DAILY SKY MOVEMENTS

IMAGINARY GLOBE

Earth’s axis of spin

THE SKY AS A SPHERE To an observer on Earth, the stars appear to move slowly across the night sky. Their motion is caused by Earth’s rotation, although it might seem that the sky is spinning around our planet. To the observer, the sky can be imagined as the inside of a sphere, known as the celestial sphere, to which the stars are fixed, and relative to which the Earth rotates. This sphere has features related to the real sphere of the Earth. It has north and south poles, which lie on its surface directly above Earth’s North and South Poles, and it has an equator (the celestial equator), which sits directly the Sun and planets above Earth’s equator. The are not fixed on the celestial sphere, but celestial sphere is like a move around on, or celestial version of a globe— close to, a circular path called the ecliptic the positions of stars and galaxies can be recorded on celestial equator—a it, just as cities on Earth circle on the celestial have their positions of latitude sphere concentric and longitude on a globe. with Earth’s equator

OBSERVER AT EQUATOR

antiquark

THE CELESTIAL SPHERE

Earth’s orbit 124

IN TR OD U CTIO N

SMOOTHER

X-boson (hypothetical)

About 10 –32 seconds after the Big Bang, the universe is thought to have been a “soup” of fundamental particles and antiparticles. These were continually formed from energy as particle–antiparticle pairs, which then met and were annihilated back to energy. Among these particles were some that still exist today as constituents of matter or as force carrier particles. These include quarks and their antiparticles (antiquarks), and bosons such as gluons (see pp.30–31). Other particles may have been present that no longer exist or are hard to detect—perhaps some gravitons (hypothetical gravity-carrying particles) and Higgs bosons, also hypothetical, which impart mass to other particles.

INFLATION

W-boson

MORE MATTER THAN ANTIMATTER

PARTICLE SOUP

Physicists believe that at the exceedingly high temperatures present just after the Big Bang, the four fundamental forces were unified. Then, as the universe cooled, the forces separated, or “froze out,” at the time intervals shown here.

In a Big Bang without inflation, what are now widely spaced regions of the universe could never have become so similar in density and temperature. Inflation theory proposes that our observable universe is derived from a tiny homogeneous patch of the original universe. The effect of inflation is like expanding a wrinkled sphere—after the WRINKLED expansion, its surface appears smooth and flat.

graviton (hypothetical)

gluon

SEPARATION OF FORCES

Celestial cycles 64–67

The thin atmosphere of Mars is dominated by carbon dioxide, with tiny amounts of nitrogen and argon and other gases, and some traces of water vapor.

nitrogen (2.7%)

THE MILKY WAY ▷

quark– antiquark pair

During this era, matter and energy were completely interchangeable. Three of the fundamental forces of nature were still unified.

Mapping the sky 348–53

ATMOSPHERIC COMPOSITION

argon (1.6%)

ULTRA-HIGH-ENERGY PROTON COLLISION

THE GRAND UNIFIED THEORY ERA

Using the sky guides 428–29

oxygen, carbon monoxide, and trace gases (0.4%)

carbon dioxide (95.3%)

NORTHERN FALL EQUINOX

In this image obtained by a detector at the Large Hadron Collider at CERN, the yellow lines show the paths of particles produced from the collision of ultra-high-energy protons.

The Big Bang was not an explosion in space, but an expansion of space, which happened everywhere. Physicists do not know what happened in the first instant after the THE PLANCK ERA Big Bang, known as the Planck era, but at No current theory of the end of this period, they believe that physics can describe gravity split from the other forces of nature, what happened in followed by the strong nuclear force (see the universe during this time. p.30). Many believe this event triggered “inflation”—a short but rapid expansion. If 3x10–26 ft/10–26 m DIAMETER 33 ft/10 m 105 m (62 miles/100 km) inflation did occur, it helps to explain why 27 1022K (18 billion trillion °F/10 TEMPERATURE 10 K (1,800 trillion trillion °F (1,000 trillion trillion °C) the universe seems so smooth and flat. THE INFLATION ERA THE QUARK ERA During inflation, a fantastic amount of Part of the universe expanded from Sometimes called the electroweak era, this period saw mass-energy came into existence, in billions of times smaller than a vast numbers of quark and antiquark pairs forming from tandem with an equal but negative proton to something between the energy and then annihilating back to energy. Gluons and amount of gravitational size of a marble and a football field. other more exotic particles also appeared. energy. By the end of 1 yoctosecond A hundred-billionth of a yoctosecond A hundred-millionth of a yoctosecond singularity TIME inflation, matter had 10 –24 seconds at the start 10 –35 seconds 10 –32 seconds of time begun to appear.

Grand Unified Force

49

EXPLORING SPACE

THE FIRST MICROSECOND

The timeline on this page and the next shows some events during the first microsecond (1 millionth of a second or 10–6 seconds) after the Big Bang. Over this period, the universe’s temperature dropped from about 1034°C (ten billion trillion trillion degrees) to a mere 1013°C (ten trillion degrees). The timeline refers to the diameter of the observable universe: this is the approximate historical diameter of the part of the universe we can currently observe.

TIME, SPACE, ENERGY, AND MATTER

THE CELESTIAL SPHERE

Mars’s orbit is highly eccentric compared to that of Earth, which means that its distance from the Sun varies more during a Martian year. A Martian day is 42 minutes longer than an Earth day.

This section is about the Sun and the many bodies in orbit around it. It covers the nine planets one by one and then looks at asteroids, comets, and meteors, as well as the remote regions on the margins of the solar system. For most planets, profiles of individual surface features or moons are also included.

△ WHAT IS THE UNIVERSE?

62

Mars orbits Sun in 687 Earth days

0.38 MARS

ATMOSPHERE AND WEATHER

45°

△ THE SOLAR SYSTEM

I NT ROD UCT I ON

nucleus nucleus

neutron

A solid metal at 70°F (21°C). Its atoms have 13 protons, 14 neutrons, and 13 electrons in 3 shells.

sodium ion

green quark

ejected electron (charge -1 )

incoming highenergy photon

EARTH

ALUMINUM

CHEMICAL COMPOUNDS

red quark gluon

electron raised to higher energy state

inner-shell electron

SIZE COMPARISON

PROPERTIES OF ELEMENTS

ABSORPTION AND EMISSION

electron at low energy state

2

water ice concentrated at cold lower latitudes

Mars spins on its axis every 24.63 hours

NORTHERN SUMMER SOLSTICE

HYDROGEN

Atoms are composed of fundamental particles called quarks and electrons. The quarks are bound in groups of three by gluons, which are massless particles of force. The quark groups form particles called protons and neutrons. These are clustered in a compact region at the center of the atom called the nucleus. Most of the rest of an atom is empty space, but moving around within this space are electrons. These carry a negative electrical charge and have a very low mass—nearly all the mass in an atom is in the protons and neutrons. Atoms always contain equal numbers of protons (positively charged) and electrons (negatively charged) and so are electrically neutral. If they lose or gain electrons, they become charged particles called ions. emitted photon

Danish physicist Niels Bohr (1885– 1962) was the first to propose that electrons in an atom move within discrete “orbits.” He suggested that these orbits have fixed energy levels and that atoms emit or absorb energy in fixed amounts (“quanta”) as electrons move between orbits. Bohr’s orbits are today called orbitals; they are substructures of electron shells.

GRAVITY AT EQUATOR (EARTH = 1)

NUMBER OF MOONS

Mars is visible to the naked eye. It is brightest when at its closest to Earth, which is approximately once every two years. It then has an average magnitude of –2.0.

water ice still present at equator

Sun

NIELS BOHR

Atoms are not all the same—they can hold different numbers of protons, neutrons, and electrons. A substance made of atoms of just one type is called a chemical element, and is given an atomic number equal to the number of protons, and thus electrons, in its atoms. Examples are hydrogen, with an atomic number of 1 (all hydrogen atoms contain one proton and one electron), helium (atomic number 2), and carbon (number 6). Altogether, there are 90 naturally occurring elements. The atoms of any element are all the same size and, crucially, contain the same configuration of electrons, which is unique to that element and gives it specific chemical properties. The universe once consisted almost entirely of the lightest elements, hydrogen and helium. Most of the others, including such common ones as oxygen, carbon, and iron, have largely been created in stars and star explosions.

ATOMS AND IONS

This image of gold atoms on a grid of green carbon atoms was made by a scanningtunneling microscope.

29

0.11

MASS (EARTH = 1)

0.15

T H E M IL KY WAY

Radiation 34–37 Space and time 40–43

NUCLEUS

A tightly bound ball of six protons (purple) and six neutrons (gold)

687 Earth days

4,213 miles (6,780 km)

VOLUME (EARTH = 1)

THE SOLAR SYSTEM

the universe’s matter is composed of fundamental particles, some of which, governed by various forces, group together to form atoms and ions. In addition to these well-understood types of matter, other forms exist. Most of the universe’s mass consists of this “dark matter,” whose exact nature is still unknown.

24–27 Celestial objects

EMPTY SPACE

Most of an atom is empty— the protons, neutrons, and electrons are all shown here much larger than their real size relative to the whole atom

ORBITAL PERIOD (LENGTH OF YEAR)

–195ºF to 77ºF (–125ºC to 25ºC)

axis of rotation tilts 60° from vertical

PERIHELION 128 million miles (207 million km)

APHELION 155 million miles (249 million km)

THE SO L AR SYSTEM

MATTER

24.63 hours

SURFACE TEMPERATURE

DIAMETER

SPIN AND ORBIT

28

ROTATION PERIOD

141.6 million miles (227.9 million km)

OBSERVATION

axis tilts from vertical by 25.2°

151

MARS PROFILE

THE NIGHT SKY This section is an text describes atlas of the night sky. features of It is divided into interest two parts. The first (the constellations) is a guide to the 88 regions into which astronomers divide the sky. It contains illustrated profiles of all the constellations, arranged according to their position in the sky with the most northerly ones first and the southernmost last. The second part (the monthly sky guide) is a month-byTHE CONSTELLATIONS ▷ Each constellation profile is month guide, containing a illustrated with a chart, two summary of the highlights maps, and one or for each month, detailed star locator more photographs. A more charts, and charts showing detailed guide to the section the positions of the planets. can be found on pp.348–49.

detailed chart 368

THE CONSTELLATIONS ANDROMEDA

Andromeda SIZE RANKING

19

BRIGHTEST STARS

Alpheratz (α) 2.1, Mirach (β) 2.1 GENITIVE

Andromedae ABBREVIATION

And

HIGHEST IN SKY AT 10 PM

October–November FULLY VISIBLE

90°N–37°S

This celebrated constellation of the northern skies depicts the daughter of the mythical Queen Cassiopeia, who is represented by a neighboring constellation. The head of the princess is marked by Alpheratz (or Sirrah )— Alpha (α) Andromedae—which is the star at the nearest corner of the Square of Pegasus, in another adjacent constellation. Long ago, Alpheratz was regarded as being shared with the

field of view and to concentrate the The light. The small companion galaxies, spre moo M32 and M110, are difficult to see through a small telescope. bino nee Gamma (γ) Andromedae, known of 9 also as Almaak or Almach (see p.277), is a double star of contrasting colors. N SPECIFIC FEATURES It consists of an orange giant star of kno On a clear night, the farthest it is magnitude 2.3 and a fainter blue of t possible to see with the naked eye companion, and it is easily seen iden is about 2.5 million light-years, a sm through a small telescope. which is the distance to the Andromeda Galaxy (see pp.312–313), a huge spiral of 2h stars similar to our own galaxy. PERSEUS 1h Also known as M31, this 50 ˚ galaxy spans several diameters of a full moon and lies high 65 in the mid-northern sky on 51 fall evenings. The naked eye sees it as a faint ϕ patch; it looks elongated, ξ 60 rather than spiral, ω Almach because it is tilted at a 40 γ1 ˚ steep angle toward NGC 891 υ M110 the Earth. When τ M31 ν looking at M31 M32 58 through a θ μ NGC 752 telescope, low magnification β Mirach must be used to π 30 give the widest ˚ constellation Pegasus, where it marked the navel of the horse. The star’s two names—Alpheratz and Sirrah—are both derived from an Arabic term that means “the horse’s navel.”

TRIANGULUM

δ

THE BLUE SNOWBALL 54

When seen through a small telescope, NGC 7662 appears as a bluish disk. Its structure is brought out only on CCD images such as this one.

ε

Alpher

η ζ PISCES

THE ANDROMEDA GALAXY 4

Only the inner parts of M31 are bright enough to be seen with small instruments. CCD images such as this bring out the full extent of the spiral arms. Below M31 on this image lies M110, while M32 is on its upper rim.

MY

H

Ac An on sac ato he Th ho Go pli do kil wh m DA

The hor An cap

T HE NI GHT SK Y

6

HEAD TO TOE 2

Andromeda is one of the original Greek constellations. Its brightest stars represent the princess’s head (α), her pelvis (β), and her left foot (γ).

THEMED PANELS

Until the 17th century ad, the idea of a celestial sphere surrounding Earth was not just a convenient fiction— many people believed it had a physical reality. Such beliefs date back to a model of the universe developed by the AND STORIES Greek philosopher Aristotle bc) and elaborated (384–322AND ASTROLOGY THE ECLIPTIC by the astronomer Ptolemy ad 85–165). Aristotle placed ( Astrology is the study of the positions and movements Earth stationary at in thethe sky in the belief of the Sun, Moon, and planets universe’s center,affairs. surrounded that these influence human At one by time, when several transparent, astronomy was applied mainly toconcentric devising calendars, spheres to which the stars, planets, astronomy and astrology were intertwined, but their Sun, and Moon attached. aims and methods have now were diverged. Astrologers pay little attention to constellations, but measure the positions of the Sun and planets in sections of the ecliptic that they call “Aries” and “Taurus,” for example. However, these sections no longer match the constellations of Aries, Taurus, and so on.

MYTHS AND STORIES ▷

As well as being studied scientifically, objects in the night sky have featured in myths, superstitions, and folklore, which form the subject of this type of panel.

sphere of “fixed” stars

JOHANNES KEPLER The German astronomer Johannes Kepler (1571–1630) discovered the laws of planetary motion. His first law states that planets orbit the Sun in elliptical paths. The next states that the closer a planet comes to the Sun, the faster it moves, while his third law describes the link between a planet’s distance from the Sun and its orbital period. Newton used Kepler’s laws to

STARGAZER

name or astronomical catalog number of feature (features without a popular name are identified by number) 246

EMISSION NEBULA

CATALOG NUMBER

IC 2944 DISTANCE FROM SUN

5,900 light-years 4.5

CENTAURUS

Between the constellations Crux and Centaurus lies the bright, busy starforming nebula IC 2944. This nebula is made up of dust and gas that is illuminated by a loose cluster of massive young stars. IC 2944 is perhaps best known for the many Bok globules that are viewed in silhouette against its backdrop. Bok globules are thought to be cool, opaque regions of molecular material that will eventually collapse to form stars. However, studies of the globules in IC 2944 have

revealed that the material of which they are composed is in constant motion. This may be caused by radiation from the loose cluster of massive young stars embedded in IC 2944. The stars’ ultraviolet radiation is gradually eroding the globules, and it is possible that this could prevent them from collapsing to form stars. In addition to radiation, the stars also emit strong stellar winds that send out material at high velocities, causing heating and erosion of interstellar material. The largest Bok globule in IC 2944 (below) is about 1.4 lightyears across, with a mass about 15 times that of the Sun.

EMISSION NEBULA

NGC 3372

Carina Nebula CATALOG NUMBER

Martin Rees General editor Robert Dinwiddie What is the Universe? The Beginning and End of the Universe The View From Earth The Solar System Philip Eales The Milky Way David Hughes Exploring Space The Solar System Iain Nicolson Glossary

Giles Sparrow Exploring Space Beyond the Milky Way

CATALOG NUMBER

DR 21

NGC 3372

DISTANCE FROM SUN

DISTANCE FROM SUN

DISTANCE FROM SUN

6,000 light-years

8,000 light-years MAGNITUDE

1

8,000 light-years

CYGNUS

CARINA

The birth of some of the Milky Way’s most massive stars has been discovered within DR 21, a giant molecular cloud spanning about 80 light-years. Infrared images have revealed an energetic group of newborn stars tearing apart the gas and dust around them. One star alone is 100,000 times as bright as the Sun. This star is ejecting hot stellar material into the surrounding molecular cloud, suggesting it may have a planet-forming disk around it.

Also known as the Eta (η) Carinae Nebula, this is one of the largest and brightest nebulae to be discovered. It has a diameter of more than 200 lightyears, stretching up to 300 light-years if its fainter outer filaments are included. Within its heart, and heating up its dust and gas, is an interesting zoo of young stars. These include examples of the most massive stars known, with a spectral type of O3 (see pp.232–33). This type of star was first discovered in the Carina Nebula, and the nebula remains the closest location of O3 stars to Earth. Also within the Carina Nebula are three Wolf–Rayet stars with spectral type WN (see pp.254–55). These stars are believed to be evolved O3 stars with very large rates of mass ejection. One of the best-known features within the Carina Nebula is the blue supergiant star Eta (η) Carinae (see p.262), embedded within part of the nebula known as the Keyhole Nebula. Recent observations made with infrared

GIGANTIC EMBRYOS

This infrared image reveals a clutch of gigantic newborn stars, shown here in green. In optical light, the surrounding molecular cloud is opaque.

EMISSION NEBULA

Trifid Nebula

Pam Spence The Milky Way

PROBING THE NEBULA

An infrared image reveals the stars lying within the nebula’s dense dust and gas. The open clusters Trumpler 14 and Trumpler 16 are visible to the left and top of the image.

telescopes reveal that portions of the Carina Nebula are moving at very high speeds—up to 522,000 mph (828,000 km/h)—in varying directions. Collisions of interstellar clouds at these speeds heat material to such high temperatures that it emits high-energy X-rays, and the entire Carina Nebula is a source of extended X-ray emission. The movement of these clouds of material is thought to be due to the strong stellar winds emitted by the massive stars within, bombarding the surrounding material and accelerating it to its high velocities.

Kevin Tildsley The Milky Way

COSMIC CONSTRUCTION

This false-color image, composed of four separate images taken in different infrared wavelengths, reveals more than 300 newborn stars scattered throughout the RCW 49 nebula. The oldest stars of the nebula appear in the center in blue, gas filaments appear in green, and dusty tendrils are shown in pink.

RCW 49 CATALOG NUMBERS

RCW 49, GUM 29 DISTANCE FROM SUN

14,000 light-years

DISTANCE FROM SUN

EXPLORING SPACE

7,600 light-years CARINA

6.3

SPITZER TELESCOPE

One of the most productive regions of star formation to have been found in the Milky Way, RCW 49 spans a distance of about 350 light-years. It is thought that over 2,200 stars reside within RCW 49, but because of the nebula’s dense areas of dust and gas, the stars are hidden from view at optical wavelengths of light. However, the infrared telescope onboard the Spitzer spacecraft (see panel, right) has recently revealed the presence of up to 300 newly formed stars. Stars have been observed at every stage of their early evolution in this area, making it a remarkable source of data for studying star formation and development. One surprising preliminary observation suggests that most of the stars have accretion disks around them. This is a far higher ratio than would usually be expected. Detailed observations of two of the disks reveal that they are composed of exactly what is required in a planet-forming system. These are the farthest and faintest potential planet-forming disks ever observed. This discovery supports the theory that planet-forming disks are a natural part of a star’s evolution. It also suggests that solar systems like our own are probably not rare in the Milky Way (see pp.296-99).

HEART OF THE TRIFID

The main image, spanning about 20 lightyears, reveals details of the NGC 6514 star cluster and the filaments of dust weaving through the Trifid Nebula. A wider view (above) shows the full breadth of the nebula.

Launched in August 2003, the Spitzer telescope is one of the largest infrared telescopes put into orbit. It has been very successful in probing the dense dust and gas that lies in the interstellar medium and has revealed features and details within star-forming clouds that have never been seen before. As Spitzer observes in infrared, its instruments are cooled almost to absolute zero, to ensure that their own heat does not interfere with the observations. A solar shield protects the telescope from the Sun.

selected features are described in double-page feature profiles

312

313

INSIDE SPITZER

GALACTIC NEIGHBORS

The Spitzer craft has a 34-in (85cm) telescope and three supercooled processing instruments.

Dark dust lanes are silhouetted against glowing gas and stars in this view of the Andromeda Galaxy and its two close companions, the dwarf elliptical galaxies M32 (upper left) and M110 (bottom).

THE MI L KY WAY

This emission nebula is one of the youngest yet discovered. It was first called the Trifid Nebula by English astronomer John Herschel because of its three-lobed appearance when seen through his 18th-century telescope. The nebula is a region of interstellar dust and gas being illuminated by stars forming within it. It spans a distance of around 50 light-years. The young star cluster at its center, NGC 6514, was formed only about 100,000 years ago. The Trifid’s lobes, the brightest of which is actually a multiple system, are created by dark filaments lying in and around the bright nebula. The whole area is surrounded by a blue 239 reflection nebula, particularly conspicuous in the upper part, where dust particles disperse light.

table of summary information (varies between sections)

locator map shows constellation in which feature can be found and its position within the constellation

M20

SAGITTARIUS

Carole Stott The Solar System

CARINA

EMISSION NEBULA

ERODING TOWER

A tower of cool hydrogen gas and dust three light-years long extends from the Carina Nebula in this false-color Hubble image. The tower is being eroded by the energy from hot, young stars nearby.

1

MAGNITUDE

CATALOG NUMBER

THE MI L KY WAY

CONTRIBUTORS

Robin Scagell The View from Earth

CATALOG NUMBER

EMISSION NEBULA

DR 21

7

Ian Ridpath The Night Sky

Carina Nebula

THACKERAY’S GLOBULES

The Bok globules in IC 2944 were first observed in 1950 by South African astronomer A.D. Thackeray. This globule has recently been shown to be two overlapping clouds.

ACTIC COLLISIONS

Profiles of notable astronomers and pioneers of spaceflight, as well as a brief summary of their achievements, appear in this type of panel.

247

IC 2944

MAGNITUDE

◁ BIOGRAPHY

EMISSION NEBULA

STAR-FORMING NEBULAE

MAGNITUDE

This type of feature is used to describe the study of space, either from Earth’s surface or from spacecraft. Individual panels describe particular discoveries or investigations.

ARISTOTLE’S SPHERES

Three types of color-coded panels are used to present a more detailed focus on selected subjects. These panels appear both on explanatory pages and MYTHS in feature profiles.

ABOUT THIS BOOK

◁ EXPLORING SPACE

EXPLORING SPACE

g of stars is created when two ies collide. Here, shock waves rippled out, triggering star tion in the interstellar material.

M OLD TO NEW

k waves and material from a nova blast spread out through terstellar medium, triggering star formation.

△ FEATURE PROFILES

Throughout the Guide to the Universe, introductory pages are often followed by profiles of a selection of specific objects. For example, the introduction to star-formation (left) is followed by profiles of actual star-forming regions in the Milky Way (above).

2.5 million light-years DIAMETER

Ecliptic 20°N

South

40°N

North

STAR MOTION

GA PE

T

SU

N S

O

S

IA

Zeniths

RO

N DA ERI

M

Planetary nebula Diffuse nebula Open cluster Globular cluster Galaxy

DEEP-SKY OBJECTS

Variable star 5 4 3

T S

A

E

EAST

U

TRIANGULUM AND MARS 2 M33 54

The clouds of pinkish gas in the arms of M33 show up in CCD images of this spiral galaxy in the Local Group. It is presented almost face-on to the Earth.

This section includes two charts for each month of the year, for observers in northern and southern latitudes. The section is described in more detail on pp.428–29.

chart on this page shows view looking north, with view to south on facing page

α alpha

ν nu

γ δ ε ζ

ο π ρ σ τ υ ϕ χ ψ ϖ

β beta

T HE NI GHT SK Y

1am

11pm

Midnight

Daylightsaving time

Ecliptic

EAST

O

2

H

S

M87

1

INA CAR

S

PPI LA

VE

XIS PY A

H

T

S

T

R

N TA

0

Canopus M41 M93

46 M

PU

M50

M47

O N

CA MA NIS JO R

N

R C

O

SEX

LOOKING SOUTH

T

ES N TIC CA NA VE

N

O

M64

SOUTH

LEPUS

COLUMBA

Rigel Sirius

S

RO

CE O

Adhara

M3

5

Betelge use

M42

ORION

Bellatrix

n

Aldebara M1

M38 M36

AU R I G A M37

DORADO

R

X

SA R U R A JO M

S

TL AN

Reg

IA

JANUARY | NORTHERN LATITUDES

M

ES HYAD

PER

CAELU

E

S

E PL

U TA

RS

N LY

M81

51

E OT

R

LMC

UM

PE

SEU

HO

US 4

DE

RU

S

S

M3

AU R I G A

lla

Cape

LOPA RDALIS

M

BO

ECLIPTI

ULU

A

ME

RETIC

ED

CA

48

67

D

PICTOR

OM

C 869

M

HY

BE COM RE A NI CE S

20°N

IUM

UL

G LO

NG

NG

4

M1 03

I

-1

TRIA

ARIES

DR

31

S

C 88

M

STAR MAGNITUDES

M

M33

U

NG

IA

Mizar

BIG E ER TH IPP D

1 M10

NA RO LIS C O REA BO

M

S

R

LEO

M53

40°N

Mira

AN

PE

M13

CE

NI

ulus

3

60°N

PIS CES

IO

Polaris

M92

U R SA MINOR

DRACO M

POINTS OF REFERENCE

ES

SS

EUS

Vega

T

Astronomers use a convention for naming some stars in which Greek letters are assigned to stars according to their brightness. These letters appear on some of the charts in this book.

Horizons

RN

FO

SC

CA

2

PH

M5

CE

LYR A

CA N

M44

L M EO IN OR

THE GREEK ALPHABET

60°N

O

U

T AX

TU

PI

CE

PH

S

39

b

US

CA

LE

S

O

IX

M

ne

De

C

YG N

A

EN

LA

9

CE RT A

M2

O

M n

yo

△ MONTHLY SKY GUIDE

This image of the three stars that make up the shape of Triangulum also includes the planet Mars, passing through neighboring Pisces.

the same star at its brightest Cepheid variable V1 at its faintest

H

S

T

Midnight

10pm

11pm

Standard time

OBSERVATION TIMES

December 15

9pm

10pm

T H E NI GHT SK Y

E

S

I

oc Pr

I

E

The study of M31 played a key role in the discovery that galaxies exist beyond our own. Although the spectra of galaxies suggested they shone with the light of countless stars, no one could measure their immense distance. In 1923, Edwin Hubble (see p.45) proved that M31 lay outside our galaxy. He found the true distance of M31 by calculating the luminosities of its Cepheid variable stars (see pp.282–83), and relating their true brightness to their apparent magnitude.

This X-ray image of a small area of M31’s core shows its central black hole as a blue dot—it is cool and inactive compared to the galaxy’s other X-ray sources (yellow dots).

THE TRIANGLE

T H E NI GH T SK Y

SPECIFIC FEATURES Triangulum contains the third-largest member of our Local Group of galaxies, M33 or the Triangulum Galaxy (see p.311). In physical terms, M33 is about one-third the size of the Andromeda Galaxy, or M31 (see pp.312–13), and is much fainter. The spiral galaxy M33 appears as a large pale patch of sky. It is similar in size to a full moon, when viewed through binoculars or a small telescope on a dark, clear night. To see the spiral arms, a large telescope is needed. M33 looks like a starfish on long-exposure photographs. There is little else of note in the constellation apart from 6 Trianguli. This yellow star has a magnitude of 5.2 and has a 7th-magnitude companion that can be detected through a small telescope.

PISCES

˚

20°N

MSEL IN DISTRESS

ARIES 20

This small northern constellation is to be found lying between Andromeda and Aries. It consists of little more than a triangle of three stars. Triangulum is one of the constellations known to the ancient Greeks, who visualized it as the Nile delta or the island of Sicily.

January 1

M33

January 15

α

40°N

6

Date

β

γ δ

TRIANGULUM

8pm

˚

90°N–52°S

IN

Po

9pm

30

60°N

R

Tri

FULLY VISIBLE

M

llux

February 1

Trianguli

HIGHEST IN SKY AT 10 PM

November–December

THS AND STORIES

e Flemish artist Rubens added the flying se Pegasus to his 17th-century depiction of dromeda’s dramatic rescue by Perseus from ptivity on the rock.

GE

r

Casto

February 15

ANDROMEDA

EROIC RESCUE

ccording to Greek mythology, ndromeda was chained to a rock n the seashore and offered as a crifice to a sea monster in onement for the boastfulness of r mother, Queen Cassiopeia. he Greek hero Perseus, flying ome after slaying Medusa, the orgon, noticed the maiden’s ght. He responded by swooping wn in his winged sandals and lling the sea monster. He then hisked Andromeda to safety and arried her.

E

2h

PERSEUS

Zeniths

GENITIVE

ABBREVIATION

20°N

˚

78

BRIGHTEST STAR

ANDROMEDA

W

40°N

40 SIZE RANKING

Beta (β) 3.0

INTERGALACTIC DISTANCE

CENTRAL BLACK HOLE

H

60°N

3h

Triangulum PEGASUS

HERCULES

Horizons

THE TRIANGLE

atz

PEGASUS

POINTS OF REFERENCE

α

CYGNUS

˚

7

BL

1 Planetary nebula

ANDROMEDA

σ

30

M5

Diffuse nebula

NGC 7662

LACERTA

Lacerta consists of a zigzag of faint stars in the northern sky, squeezed between Andromeda and Cygnus like a lizard between rocks. It is one of the seven constellations invented by Johannes Hevelius (see p.384) during the late 17th century. This constellation contains no objects of note for amateur astronomers, although BL Lacertae (see p.325), which was once thought

NORTH

2

6

LACERTA

L O O K I N G N O RT H

NGC 7243

5 11 15

ANDROMEDA

90°N–33°S

ο

Open cluster

κ ι

Globular cluster

4

α

Lac

FULLY VISIBLE

7

Galaxy

β

9

DEEP-SKY OBJECTS

˚

10

8

Variable star

22h

CEPHEUS

50

HIGHEST IN SKY AT 10 PM

λ

5

23h THE LIZARD

3

ψ

4

ABBREVIATION

0h

to be a peculiar 14th-magnitude variable star, has given its name to a class of galaxies with active nuclei called BL Lac objects or “blazars.” A BL Lac object is a type of quasar that shoots jets of gas from its center directly toward the Earth. Because we see these jets of gas head-on, these BL Lac objects tend to look starlike.

September–October 23h 0h

3

GENITIVE

2

68

BRIGHTEST STAR

Lacertae

EXPLORING SPACE

W

1

SIZE RANKING

Alpha (α) 3.8

WEST

0

THE LIZARD

Lacerta

369

GALAXY CORE

This X-ray image of the central area of M31 shows numerous point X-ray sources and a diffuse cloud of gas (in orange), which is being heated by shock waves from supernova explosions.

as typical a spiral galaxy as it appears. For example, despite its huge size, it appears to be less massive than the Milky Way, with a sparse halo of dark matter. Despite this, astrophysicists calculate that M31’s central black hole has the mass of 30 million Suns, almost ten times more than the Milky Way’s central black hole. The huge mass of M31’s black hole is surprising, because a galaxy’s black hole is thought generally to reflect the mass of its parent galaxy. Furthermore, studies at different wavelengths have revealed disruption in the galaxy’s disk, possibly caused by an encounter with one of its satellite galaxies in the past few million years. M31 and the Milky Way are moving toward each other, and they should collide and begin to coalesce in around 5 billion years.

333

R

-1

e open star cluster NGC 752 ads over an area larger than a full on and can be identified with oculars, but a small telescope is ded to resolve its individual stars th magnitude and fainter. NGC 7662, which is popularly wn as the Blue Snowball, is one he easiest planetary nebulae to ntify, and it can be found through mall telescope.

STAR MAGNITUDES

THE CONSTELLATIONS

B E Y ON D T H E M IL KY WAY

This section looks at features found beyond our own galaxy, including other galaxies and galaxy clusters and superclusters, the largest known structures in the universe.

JANUARY | NORTHERN LATITUDES

artwork of figure depicted by constellation

The Andromeda Galaxy (M31) is the closest major galaxy to the Milky Way and the largest member of the Local Group of galaxies. Its disk is twice as wide as our galaxy’s. M31’s brightness and size mean it has been studied for longer than any other galaxy. First identified as a “little cloud” by Persian astronomer Al-Sufi (see p.421) in around ad 964, it was for centuries assumed to be a nebula, at a similar distance to other objects in the sky. Improved telescopes revealed that this “nebula,” like many others, had a spiral structure. Some

BEYOND THE MILKY WAY ▷

332

locator shows constellation in context

astronomers thought that M31 and other “spiral nebulae” might be solar systems in the process of formation, while others guessed correctly that they were independent systems of many stars. It was in the early 20th century that Edwin Hubble (see p.45) revealed the true nature of M31, at a stroke hugely increasing estimates of the size of the universe (see panel, opposite). Astronomers now know that M31, like the Milky Way, is a huge galaxy attended by a cluster of smaller orbiting galaxies, which occasionally fall inward under M31’s gravity and are torn apart. Despite being intensively studied, the Andromeda Galaxy still holds many mysteries, and it may not be

3.4

MAGNITUDE

WEST

ADOLESCENT STAR

T Tauri (above) is the prototype of a type of adolescent star that is still undergoing gravitational contractions. These stars have extensive accretion discs and violent stellar winds coming from their poles (left).

accretion disk

M31, NGC 224 DISTANCE

T H E M IL KY WAY

polar gas jets

CATALOG NUMBERS

250,000 light-years

ANDROMEDA

B E Y ON D T H E M IL KY WAY

ollapsing fragments of nebulae continue to shrink, their matter coalesces and tracts to form protostars. These stellar fledglings release a great deal of energy as y continue to collapse under their own gravity. However, they are not easily seen ause they are generally surrounded by the remnants of the cloud from which they med. The heat and pressure generated within protostars acts against the gravity of r mass, opposing the collapse. Eventually, matter at the centers of the protostars gets so hot and dense that nuclear fusion starts and a star is born. At this stage, stars are very unstable. They lose mass by expelling strong stellar winds, n which are often directed in two 26) opposing jets channeled by a disk of dust and gas that forms sters around their equators. Gradually, and ber. At the balance between gravity and was not pressure begins to equalize and bjects the stars settle down on to the Dreyer main sequence (see pp.234–37).

Sb SPIRAL GALAXY

Andromeda Galaxy

PTO

OWARD THE MAIN SEQUENCE

themed panel (see above)

UL

en they have formed from the fragmentation of a single collapsing molecular d, young stars are often clustered together. Many stars are formed so close to their hbors that they are gravitationally bound, and some are even close enough to sfer material. It is unusual for a star not to be in a multiple system such as a binary (see pp.274–75), and in this respect, the Sun is uncommon. Stars within a cluster ally have a similar chemical composition, although, since successive generations of may be produced by a single nebula, clusters may contain stars of different ages pp.288–89). Remnants of dust and gas from the initial cloud will linger, and the grains often reflect the starlight, predominantly in the shorter blue wavelengths. Thus, young star clusters are often surrounded by distinctive blue reflection nebulae. Young stars are hot ENT STAR FORMATION and bright, and any nearby interstellar material will g star clusters (blue) and starng regions (pink) abound in NGC be heated by new stars’ heat, producing red emission A. As the galaxy’s gas collides nebulae. Stars’ individual motions will eventually the intergalactic medium through cause a young star cluster to dissipate, though h the galaxy is traveling, the multiple stellar systems may remain gravitationally ing pressure triggers violent but ing star-cluster formation. bound and may move through a galaxy together.

SC

TAR CLUSTERS

lines on chart show reference points for observers at different latitudes

gamma delta epsilon zeta η eta θ theta ι iota κ kappa λ lambda μ mu

ξ xi

omicron pi rho sigma tau upsilon phi chi psi omega

THE PACIFIC OCEAN

This view of Earth, taken from the Space Shuttle, is dominated by the Pacific Ocean. Above the water are clouds of water vapor and a volcanic ash plume, a reminder of the continuing geological activity of the planet’s interior.

A SHORT TOUR OF THE UNIVERSE the night sky has always evoked mystery and wonder. Since antiquity, astronomers Many of humankind’s have tried to understand the patterns of first ventures into space the “fixed stars,” and the motions of the were set in motion on the Moon and planets. The motive was partly launch pads of Kennedy a practical one, but there has always been Space Center. This remains the busiest launch and a more “poetic” motivation, too—a landing site of the US quest to understand our place in nature. space program, and it is Modern science reveals a cosmos far also the main base for the vaster and more varied than our ancestors Space Shuttle. could have envisioned. No continents on Earth remain to be discovered. The exploratory challenge has THE FLORIDA COAST now broadened to the cosmos. Humans The islands and reefs of have walked on the Moon; uncrewed the Florida Keys are seen here from Earth orbit. The spacecraft have beamed back views of all reefs are partly made of the planets; and some people now living living organisms, in the may one day walk on Mars. form of corals. To date, The stars, fixed in the “vault of life has not been found heaven,” were a mystery to the ancients. anywhere other than on Earth, but the search for They are still unattainably remote, but we alien life will be perhaps know that many of them are shining even the most fascinating more brightly than the Sun. Within the quest of the 21st century. last decade, we have learned something remarkable that was long suspected: many stars are, like our Sun, encircled by orbiting planets. The number of known planetary systems already runs into hundreds—there could, all together, be a billion in our galaxy. Could some of these planets resemble the Earth, and harbor life? Even intelligent life? All the stars visible to the unaided eye are part of our home galaxy—a structure so vast that light takes a hundred thousand years to cross it. But this galaxy, the Milky Way, is just one of billions visible through large telescopes. These galaxies are hurtling away from each other, as though they had all originated in a “big bang” 13 or 14 billion years ago. But we don’t know what banged, nor why it banged. The beauty of the night sky is a common experience of people from all cultures; indeed, it is something that we share with all generations since prehistoric times. Our modern perception of the “cosmic environment” is even grander. Astronomers are now setting Earth in a cosmic context. They seek to understand how the cosmos developed its intricate complexity—how the first galaxies, stars, and planets formed and how, on at least one planet, atoms assembled into creatures able to ponder their origins. This book sets humanity’s concept of the cosmos in its historic context, and presents the latest discoveries and theories. It is a beautiful “field guide” to our cosmic habitat: it should enlighten and delight anyone who has looked up at the stars with wonder, and wished to understand them better. Martin Rees KENNEDY SPACE CENTER

THE MOON 1.3 light-seconds from Earth

The Earth is seen here rising above the horizon of its satellite, the Moon. Our home planet’s delicate biosphere contrasts with the sterile moonscape on which the Apollo astronauts left their footprints.

The Sun

OUR LOCAL STAR

The Sun dominates the solar system. Our chief source of heat and light, it also holds Earth and the rest of the planets in their orbits. This ultraviolet image reveals the dynamic activity in the ultra-hot corona above the Sun’s visible surface. A SOLAR FLARE

The Sun usually appears to the unaided eye as a bright but featureless disk. However, during a total solar eclipse, when light from the disk is blocked out by the Moon, violent flares in the outer layers of the atmosphere can be seen more clearly.

ULTRA-HOT CORONA

The gas in the Sun’s corona is heated to several million degrees, causing it to emit X-rays, which show up in this image taken by the Japanese YOHKOH satellite. The dark areas are regions of low-density gas that emit a stream of particles, known as the solar wind, into space. PROMINENCES

In the corona, electrified gas called plasma forms into huge clouds known as prominences, flowing through the Sun’s magnetic field. As the prominence in this image erupts, it hurls plasma out of the Sun’s atmosphere and into space.

SUNSPOTS ON THE SOLAR SURFACE 8 light-minutes from Earth

These regions, cooler and darker than the rest of the Sun’s surface, are sustained by strong magnetic fields. Some sunspots are large enough to engulf the Earth. Sunspot numbers vary in cycles that take about 11 years to complete, and peaks in the cycle coincide with disturbances, such as aurorae, in our own atmosphere.

CANYONS ON MARS 4 light-minutes from Earth

Mars is one of the solar system’s four inner rocky planets. This image (with exaggerated vertical scale) shows part of the Valles Marineris, a vast canyon system. SATURN AND ITS RINGS 71 light-minutes from Earth

There are rings of dust and ice particles in nearly circular orbits around all four of the giant gas planets, but those around Saturn are especially beautiful. This close-up was taken by the Cassini spacecraft.

IO 34 light-minutes from Earth

Jupiter has 64 known moons—and there are almost certainly others yet to be discovered. Io, Jupiter’s innermost moon, is seen here moving in front of the turbulent face of the planet.

433 EROS 3.8 light-minutes from Earth

A vast number of asteroids are in independent orbit around the Sun. Eros is marked by the impact of much smaller bodies. This image was taken by the NEAR–Shoemaker craft from only 60 miles (100 km) above the surface.

The planets

JUPITER’S GREAT RED SPOT 34 light-minutes from Earth

The gas giant Jupiter is more massive than all the other planets in the solar system combined. Its mysterious swirling vortex, the Great Red Spot, has been known since the 17th century, but our knowledge of Jupiter improved greatly when the planet was visited by uncrewed spacecraft in the 1970s. This image of the Great Red Spot was taken in 1979 by Voyager 1, using filters that exaggerate its colors.

Stars and galaxies

THE CENTER OF OUR GALAXY 25,000 light-years from Earth

The center of our galaxy, the Milky Way, is thought to harbor a black hole as heavy as 3 million Suns. This image reveals flare-ups in Xray activity close to the event horizon, the point of no return for any objects or light that approach the black hole.

CENTAURUS A 15 million light-years from Earth

Not all galaxies exist in isolation; occasionally, they interact. Centaurus A is far more “active” than our own galaxy. It has an even bigger black hole than the Milky Way’s, and its gravity may have captured and “cannibalized” a smaller neighbor. THE WHIRLPOOL GALAXY 31 million light-years from Earth

The Whirlpool is involved in another case of galaxy interaction. A spinning, disklike galaxy, viewed face-on, its spiral structure may have been induced by the gravitational pull of a smaller satellite galaxy (at the top of this picture).

THE ORION NEBULA 1,500 light-years from Earth

The Orion Nebula is a vast cloud of glowing dusty gas within the Milky Way, inside which new stars are forming. The nebula contains bright blue stars much younger than the Sun, and some protostars whose nuclear power sources have not yet ignited.

The limits of time and space

GALAXY SUPERCLUSTERS

This image, generated by plotting the positions of 15,000 galaxies, depicts the main “topographic” features of our cosmic environment out to 700 million light-years from Earth. The yellow blobs are superclusters of galaxies, which are interspersed with black voids.

LARGE-SCALE STRUCTURES

This view of the sky, in infrared light, shows how galaxies outside the Milky Way are distributed in clusters and filamentary structures. The galaxies are color-coded according to brightness, with bright ones in blue and faint ones in red.

DISTANT CLUSTER OF GALAXIES

This massive cluster of galaxies is one of the most distant known to astronomers, some 8.5 billion light-years from Earth. Superimposed on the optical picture is an X-ray image revealing hot gas (shown in purple) that pervades the cluster.

DWARF GALAXIES BURSTING INTO LIFE 9 billion light-years from Earth

Tiny young galaxies brimming with stars in the process of formation, some 9 billion light-years away, are seen in this image taken at near-infrared wavelengths by the Hubble Space Telescope. They stand out in the image because energy from the new stars has caused oxygen in the gas around them to light up like a neon sign. This phase of rapid star birth is thought to represent an important stage in the formation of dwarf galaxies, the most numerous type of galaxy in the universe.

INTRODUCTION

I N TRO D UC TI O N

20

“There are grounds for cautious optimism that we may now be near the end of the search for the ultimate laws of nature.” Stephen Hawking

THE UNIVERSE IS ALL OF EXISTENCE— all of space and time and all the matter and energy within it. The universe is unknowably vast, and ever since it formed, it has been expanding, carrying distant regions apart at speeds up to, and in some cases possibly exceeding, the speed of light. The universe encompasses everything from the smallest atom to the largest galaxy cluster, and yet it seems that all are governed by the same basic laws. All visible matter (which is only a small percentage of the total matter) is built from the same subatomic blocks, and the same fundamental forces govern all interactions between these elements. Knowledge of these cosmic operating principles—from general relativity to quantum physics—informs cosmology, the study of the universe as an entity. Cosmologists hope to answer questions such as “How big is the universe?”, “How old is it?”, and “How does it work, on the grandest scale?”. BOW SHOCK AROUND A STAR

This mysterious image from the Orion Nebula shows how matter and radiation interact on a stellar scale. A star surrounded by gas and dust has met a fierce wind of particles blowing from a bright young star (out of frame). Around the star, a crescent-shaped gaseous bow shock has built up, like water flowing past the prow of a boat.

WHAT IS THE UNIVERSE?

22

WHAT IS THE UNIVERSE?

THE SCALE OF THE UNIVERSE Celestial objects 24–27 Expanding space 44–45 The fate of the universe 58–59 The family of the Sun 102–103 The Milky Way 226–29 Beyond the Milky Way 300–39

EVERYTHING IN THE UNIVERSE

is part of something larger. The scale of the Earth and its moon may be relatively easy for the human mind to grasp, but the nearest star is unimaginably remote, and the farthest galaxies are billions of times more distant yet. Cosmologists, who study of the size and structure of the universe, use mathematical models to build a picture of the universe’s vast scale. the stellar neighborhood lies in the Orion Arm of the Milky Way, some 26,000 light-years from its center

THE SIZE OF THE UNIVERSE

galaxy NGC 147

the Andromeda Galaxy, 2.65 million lightyears from the Milky Way

galaxy NGC 185

Andromeda I Andromeda II Andromeda III Triangulum Galaxy

galactic nucleus

Cosmologists may never determine exactly how big the universe is. It could be infinite. Alternatively, it might have a finite volume, but even a finite universe would have no center or boundaries and would curve in on itself. So, paradoxically, an object traveling off in one direction would eventually reappear from the opposite direction. What is certain is that the universe is expanding and has been doing so since its origins in the Big Bang, 13.7 billion years ago (see p.48). By Alpha studying the patterns of radiation left from Centauri the Big Bang, cosmologists can estimate the minimum size of the universe, Sun should it turn out to be finite. Some parts must be separated by at least tens of billions of light-years. Since a light-year is the distance Sirius that light travels in a year, (5.878 trillion miles, or 9.46 trillion km), the universe is bewilderingly big.

5,000 light-years

THE MILKY WAY

orbit of Pluto asteroid belt 5 lightyears

Sun

The solar system and its stellar neighbors are a tiny part of the Milky Way galaxy, a disk of 200 billion stars and some enormous clouds of gas and dust. The Milky Way is over 100,000 light-years across and has a supermassive black hole at its central nucleus.

Earth

THE STELLAR NEIGHBORHOOD Earth

1 light-hour

I N TR OD U C TI ON

THE SOLAR SYSTEM

the Moon moves around the Earth in a slightly elliptical orbit

0.5 light-seconds

The Earth–Moon system is part of the solar system, comprising our local star, the Sun, and all the objects that orbit it, including comets 1.6 light-years away. Neptune, the outermost planet, is on average 2.8 billion miles (4.5 billion km) from the Sun.

The closest star system to the Sun, Alpha Centauri, lies 4.35 lightyears, or 25 trillion miles (40 trillion km), away. Within 20 light-years of the Sun are 79 star systems containing 106 stars. The total includes binary stars—two stars within the same system. These binary stars include Sirius, the brightest star in the sky. Most of the rest are small, dim, red stars.

THE EARTH AND MOON

Earth has a diameter of 7,930 miles (12,760 km), while the diameter of the Moon’s orbit around Earth is about 480,000 miles (770,000 km). A space probe sent to the Moon takes around two to three days to get there.

DISTANT OBJECTS

The red patches in this Hubble Space Telescope false-color image are some of the most remote objects ever detected. The light from them began its journey toward us about 13 billion years ago.

VIEW FROM EARTH

The Milky Way galaxy is a complex 3-D structure, but from our position within it, it appears as a 2-D band across the sky (above).

THE SCALE OF THE UNIVERSE DISTANT GALAXY CLUSTER

THE LOCAL SUPERCLUSTER

THE LOCAL GROUP OF GALAXIES

The Milky Way is one of a cluster of galaxies, called the Local Group, that occupies a region 10 million light-years across. It contains around 50 known galaxies, only one of which—the Andromeda Galaxy— is bigger than the Milky Way. Most others are small (dwarf) galaxies.

23

The vast galaxy cluster Abell 2218 (left) is visible from Earth even though it is more than 2 billion light-years away.

The Local Group of galaxies, together with some nearby galaxy clusters, such as the giant Virgo Cluster, is contained within a vast structure called the Virgo Supercluster. It is 100 million light-years across and (if dwarf galaxies are included) contains tens of thousands of galaxies.

LARGE-SCALE STRUCTURE

Galaxy superclusters clump into knots or extend as filaments that can be billions of light-years long, with large voids separating them. However, at the largest scale, the density of galaxies, and thus all visible matter, in the universe is uniform.

Ursa Minor dwarf galaxy Milky Way

250,000 light-years Leo A 10 million light-years

THE OBSERVABLE UNIVERSE

OVERLAPPING OBSERVABLE UNIVERSES

Earth and Planet X—an imaginary planet with intelligent life, located tens of billions of light-years away— would have different observable universes. These may overlap, as shown here, or they may not.

FROM HOME PLANET TO SUPERCLUSTERS observable universe for Planet X

observable universe for Earth

cosmic light horizon for Earth (edge of observable universe)

The universe has a hierarchy of structures. Earth is part of the solar system, nested in the Milky Way, which in turn is part of the Local Group. The Local Group is just part of one of millions of galaxy superclusters that extend in sheets and filaments throughout the observable universe.

I N TRO D UC T I ON

Although the universe has no edges and may be infinite, the part of it that scientists have knowledge of is bounded and finite. Called the observable universe, it is the 100 million spherical region around Earth from which light has light-years had time to reach us since the universe began. The boundary that separates this region from the rest of the universe is called the cosmic light horizon. Light reaching Earth from an object very close to this horizon must have been traveling for most of the age of the universe, that is, approximately 13.7 billion years. This light must have traveled a distance of around 13.7 billion light-years to reach Earth. Such a distance can be defined as region Planet X a “lookback” or “light-travelobservable from both planets time” distance between Earth and the distant Earth object. However, the true distance is much greater, because since the light arriving at Earth left the object, the object has been carried farther away by the universe’s expansion (see p.45).

24

WHAT IS THE UNIVERSE?

CELESTIAL OBJECTS The family of the Sun 102–103 Stars 232–33 The life cycles of stars 234–37 Extra-solar planets 296–97 Types of galaxy 302–303 Galaxy clusters 326–27 Galaxy superclusters 336–39

THE UNIVERSE CONSISTS of energy, space, and matter. Some of the matter drifts through space as single atoms or simple gas molecules. Other matter clumps into islands of material, from dust motes to giant suns, or implodes to form black holes. Gravity binds all of these objects into the great clouds and disks of material known as galaxies. Galaxies in turn fall into clusters and finally form the biggest celestial objects of all—superclusters.

GAS, DUST, AND PARTICLES

DARK NEBULA

I N TR OD U CT I ON

A globule of dust and dense gas, Barnard 68 is an example of a dark nebula. The thick dust obscures the rich star field behind it.

GLOWING GAS

This ocean of glowing gas is an active region of star formation in the Omega Nebula, an emission nebula. Clouds of gas and dust may give birth to stars and planets, but they are also cast off by dying stars, eventually to be recycled into the next stellar generation.

Much of the ordinary matter of the universe exists as a thin and tenuous gas within and around galaxies and as an even thinner gas between galaxies. The gas is made mainly of hydrogen and helium atoms, but some clouds inside galaxies contain atoms of heavier chemical elements and simple molecules. Mixed in with the galactic gas clouds is dust—tiny solid particles of carbon or substances such as silicates (compounds of silicon and oxygen). Within galaxies, the gas and dust make up what is called the interstellar medium. Visible clumps of this medium, many of them the sites of star formation, are called nebulae. Some, called emission nebulae, produce a brilliant glow as their constituent atoms absorb radiant energy from stars and reradiate it as light. In contrast, dark nebulae are visible only as smudges that block out starlight. Particles of matter also exist in space in the form of cosmic rays—highly energetic subatomic particles traveling at high speed through the cosmos.

STAR-FORMING NEBULA

The Carina Nebula, a giant cloud of gas, is a prominent feature of the sky in the Southern Hemisphere and is visible to the naked eye. Different colors in this image represent temperature variations in the gas.

CELESTIAL OBJECTS

25

STARS AND BROWN DWARFS The universe’s light comes mainly from stars—hot balls of gas that generate energy through nuclear fusion in their cores. Stars form from the condensation of clumps of gas and dust in nebulae, and sometimes occur in pairs or clusters. Depending on their initial mass, stars vary in color, surface temperature, brightness, and life span. The most massive stars, known as giants and supergiants, are the hottest and brightest, but last for only a few million years. Low-mass stars (the most numerous) are small, dim, red, and may live for billions of years; they are called red dwarfs. Smaller still are brown dwarfs. These are failed stars, not massive or hot enough to sustain the type of fusion that occurs in stars, and SUPERGIANT DOUBLE STAR emit only a dim glow. The supergiant star Betelgeuse is a binary, or double star, Brown dwarfs may account appears here as a disk because Izar consisting of a bright yellowfor much of the ordinary it is so big, even though it is orange primary star and a 500 light-years away. matter in the universe. dimmer, bluish companion.

BROWN DWARF

The dot to the right of center in this picture is a brown dwarf called Gliese 229b. The bigger, brighter object is the red dwarf star Gliese 229, around which it orbits.

GLOBULAR CLUSTER

Star clusters such as M3, above, are ancient objects that orbit galaxies. M3 has about half a million stars.

STAR REMNANTS

PLANETARY NEBULA

This glowing cloud of gas, called NGC 6751, was ejected several thousand years ago from the hot, white dwarf star visible at its center.

Stars do not last forever. Even the smallest, longestlived red dwarfs eventually fade away. Stars of medium mass, such as the Sun, expand into large, low-density stars called red giants before they blow off most of their outer layers. They then collapse to form white dwarf stars that gradually cool and fade. The expanding shells of blown-off matter surrounding such stars are called planetary nebulae (although they have nothing to do with planets). More massive stars have even more spectacular ends, disintegrating in explosions called supernovae. The expanding shell of ejected matter may be seen for thousands of years and is called a supernova remnant. Not all of the star’s material is blown off, however. Part of the core collapses to a compact, extremely dense object called a neutron star. The most massive stars of all collapse to black holes (see p.26).

SUPERNOVA REMNANT

The Veil Nebula is the shock wave from a a star that exploded 5,000–15,000 years ago. It is 2,600 light-years away, and its material may one day form new stars.

PLANETS AND SMALLER BODIES GALILEAN MOONS

Other than Earth’s own Moon, these four large moons orbiting the planet Jupiter were the first ever discovered, by Galileo Galilei in 1610. GANYMEDE

CALLISTO

coma

gas tail dust tail

COMET IKEYA–ZHANG

A few comets travel in orbits that bring them close to the Sun. Frozen chemicals in the comet then vaporize to produce a glowing coma (head) and long tails of dust and gas. This bright comet was visible in 2002.

I N TR OD U CT I ON

The solar system (our own star, the Sun, and everything that orbits it) is thought to have formed from dust and gas that condensed into a spinning disk called a protoplanetary disk. The central material became the Sun, while the outer matter IO EUROPA formed planets and other small, cold objects. A planet is a sphere, at least 1,000 miles (1,500 km) across, orbiting a star and, unlike brown dwarfs, producing no nuclear fusion. Since planets and protoplanetary disks are found orbiting stars elsewhere in our galaxy, it is probable that the solar system is typical, and that planets are common in the universe. In the solar system, the planets are either gas giants, such as Jupiter, or smaller, rocky bodies, such as Earth and Mars. Still smaller objects fall into five categories. Moons are objects that orbit planets or asteroids. Asteroids are rocky bodies of about 150 ft (50 m) to 600 miles (1,000 km) across. Comets are chunks of ice and rock, a few miles in diameter, that orbit in the far reaches PLANET EARTH of the solar system. Ice dwarfs are Our home planet seems similar but are up to a few hundred unusual in having surface miles across. Meteoroids are the water and supporting life. remains of shattered asteroids or We do not know how rare dust from comets. this is in the universe.

26

WHAT IS THE UNIVERSE?

GALAXIES The solar system occupies just a tiny part of an enormous, diskshaped structure of stars, gas, and dust called the Milky Way galaxy. Until around a hundred years ago, our galaxy was thought to comprise the whole universe; few people QUASAR imagined that anything might exist Some, if not most, outside of the Milky Way. Today, we galaxies are thought know that just the observable part to have been quasars of our universe contains more than earlier in their life. 100 billion separate galaxies. They Quasars are extremely luminous galaxies vary in size from dwarf galaxies, a powered by matter few hundred light-years across and falling into a massive, containing a few million stars, to central black hole. giants spanning several hundred thousand light-years and containing several trillion stars. As well as stars, galaxies contain clouds of gas, dust, and dark matter (see opposite), all held together by gravity. They come in five shapes: spiral, barred spiral, elliptical (spherical to football-shaped), lenticular (lens-shaped), and irregular. Astronomers identify galaxies by their number in one of several databases of celestial objects. For example, NGC 1530 indicates galaxy 1530 in a database called the New General Catalog (NGC). SPIRAL GALAXY

This image taken by the Spitzer Space Telescope shows a nearby spiral galaxy called M81. The sensor captured infrared radiation, rather than visible light, and the image highlights dust in the galaxy’s nucleus and spiral arms.

BARRED SPIRAL

In a barred spiral galaxy, such as NGC 1530, above, the spiral arms radiate from the ends of the central barlike structure, rather than from the nucleus.

galactic nucleus, or core

spiral arm

I N TRO D UC TI O N

BLACK HOLES

hot gas bubble

A black hole is a region of space containing, at its center, some matter squeezed into a point of infinite density, called a singularity. Within a spherical region around the singularity, the gravitational pull is so great that nothing, not even light, can escape. Black holes can therefore be detected only from the behavior of material around them; those discovered so far typically have a disk of gas and dust spinning around the hole, throwing off hot, high-speed jets of material or emitting radiation (such as X-rays) as matter falls into the hole. There are two main types of black hole—supermassive and stellar. Supermassive black holes, which can have a mass equivalent to billions of suns, exist in the centers of most galaxies, including our own. Their exact origin is not yet understood, but they may be a byproduct of the process of galaxy formation. Stellar black holes form from the collapsed remains of exploded supergiant stars (see p.267), and may be very common in all galaxies. STELLAR BLACK HOLE

The black hole SS 433 is situated in the center of this false-color X-ray image. It is detectable because it is sucking in matter from a nearby star and blasting out material and X-ray radiation, visible here as two bright yellow lobes.

GALACTIC BLACK HOLE

A huge bubble of hot gas rises from a disk of dust spinning around what is thought to be a supermassive black hole in the center of a nearby galaxy, NGC 4438.

spinning disk of dust and gas location of black hole

CELESTIAL OBJECTS

27

GALAXY CLUSTERS Galaxies are bound by gravity to form clusters of about 20 to several thousand. Clusters vary from 3 to 30 million light-years across. Some have a concentrated central core and a well-defined spherical structure; others are irregular in shape and structure. The cluster of galaxies that contains our own galaxy is called the Local Group. The neighboring Virgo Cluster is a large, irregular cluster of several hundred galaxies, HICKSON COMPACT GROUP lying 50 million light-years away. This cluster includes a face-on spiral Chains of a dozen or so galaxy galaxy in the center of the image, clusters are linked loosely by two closer oblique spirals, and an elliptical galaxy at lower right. gravity and make up superclusters, which can be up to 200 million light-years in extent. Superclusters in turn are arranged in broad sheets and filaments, separated by voids of about 100 million lightyears across. The sheets and voids form a network that permeates the entire observable universe. RICH CLUSTER

One of the most massive galaxy clusters known, Abell 1689 is thought to contain hundreds of galaxies (colored gold here).

DARK MATTER AND DARK ENERGY There is far more matter in the universe than is contained in stars and other visible objects. The invisible mass is called “dark matter.” Its composition is unknown. Some might take the form of MACHOs (massive compact halo objects)—dark, planetlike bodies—or WIMPs (weakly interacting massive particles)—exotic subatomic entities that scarcely interact with ordinary matter. Evidence for dark matter includes the motion of galaxies in clusters. They move faster than can be explained by the gravity of visible matter—there must be further mass present. Even if all the dark matter deduced from observations is included, the density of the universe is not sufficient to satisfy theories of its evolution. To find a solution, cosmologists have proposed the existence of “dark DARK-MATTER DISTRIBUTION. energy,” a force that counteracts This image from a computer simulation gravity and causes the universe shows the way in which dark matter to expand faster (see p.58). The (red clumps and filaments) must be exact nature of dark energy is distributed within the galaxy still speculative. superclusters in our local universe. EXPLORING SPACE

THE SEARCH FOR DARK MATTER

Nicknamed “the Tadpole,” this galaxy lies 420 million light-years away. Like any galaxy, it is a vast, spinning wheel of matter bound together by gravity. In clusters, gravity can also rip galaxies apart. The streamer of stars emerging from this galaxy is thought to have been torn out by the gravity of a smaller galaxy passing close by.

NEUTRINO DETECTOR

Neutrinos are extremely difficult to detect. This instrument is full of oil during operation. The numerous photomultiplier tubes detect flashes of light as neutrinos collide with the oil.

I N TRO D U CT I ON

DISTORTED GALAXY

To find dark matter, scientists are investigating some of the several forms it could take. Underground detectors search for evasive particles, such as WIMPs and neutrinos. Neutrinos are so tiny, they were once thought to be massless, but they do have a minute mass. There are so many neutrinos in the cosmos that their combined mass could account for 1–2 percent of the universe’s dark matter. WIMPs, if detected, could account for far more.

28

WHAT IS THE UNIVERSE?

MATTER

EMPTY SPACE

EXAMINED AT THE TINIEST SCALE,

the universe’s matter is composed of fundamental particles, some of which, governed by various forces, group together to form atoms and ions. In addition to these well-understood types of matter, other forms exist. Most of the universe’s mass consists of this “dark matter,” whose exact nature is still unknown.

24–27 Celestial objects Radiation 34–37 Space and time 40–43 The Big Bang 48–51 Out of the darkness 54–55 The Sun 104–107

WHAT IS MATTER?

Most of an atom is empty— the protons, neutrons, and electrons are all shown here much larger than their real size relative to the whole atom

STRUCTURE OF A CARBON ATOM

At the center of an atom is the nucleus, which contains protons and neutrons. Electrons move around within two regions, called shells, surrounding the nucleus. The shells appear fuzzy because electrons do not move in defined paths.

OUTER ELECTRON SHELL

Region in which four electrons orbit

Matter is anything that possesses mass—that is, anything affected by gravity. Most matter on Earth is made of atoms and ions. Elsewhere in the universe, however, matter exists under a vast range of conditions and takes a variety of forms, from thin interstellar medium (see p.228) to the matter in infinitely dense black holes (see p.267). Not all of this matter is made of atoms, but all matter is made of some kind of particle. Certain types of particle are fundamental—that is, they are not made of smaller sub-units. The most common particles within ordinary matter are quarks and electrons, which make up atoms and ions and form all visible matter. Most of the universe’s matter, however, is not ordinary matter, but dark matter (see p.27), LUMINOUS MATTER perhaps composed partly of These illuminated gas clouds neutrinos, theoretical WIMPs in interstellar space are (weakly interacting massive made of ordinary matter, composed of atoms and ions. particles), or both.

INNER ELECTRON SHELL

Region within which two electrons orbit

ATOMS AND IONS

IMAGING THE ATOM

This image of gold atoms on a grid of green carbon atoms was made by a scanningtunneling microscope.

Atoms are composed of fundamental particles called quarks and electrons. The quarks are bound in groups of three by gluons, which are massless particles of force. The quark groups form particles called protons and neutrons. These are clustered in a compact region at the center of the atom called the nucleus. Most of the rest of an atom is empty space, but moving around within this space are electrons. These carry a negative electrical charge and have a very low mass—nearly all the mass in an atom is in the protons and neutrons. Atoms always contain equal numbers of protons (positively charged) and electrons (negatively charged) and so are electrically neutral. If they lose or gain electrons, they become charged particles called ions. emitted photon

incoming photon electron at low energy state nucleus nucleus

ABSORPTION

EMISSION

electron falls back to lower energy state

ABSORPTION AND EMISSION

The electrons in atoms can exist in different energy states. By moving between energy states, they can either absorb or emit packets, or quanta, of energy. These energy packets are called photons. electron at high energy state

red quark gluon

I N TRO D UC TI O N

electron raised to higher energy state

inner-shell electron

green quark

ejected electron (charge -1 )

incoming highenergy photon

nucleus empty shell

nucleus electron in outer shell neutron proton

ATOM (NEUTRAL, NO CHARGE)

blue quark

ION (CHARGE +1)

IONIZATION

One way an atom may become a positive ion is by the electron’s absorbing energy from a high-energy photon and, as a result, being ejected, along with its charge, from the atom.

neutron

proton

MATTER NUCLEUS

A tightly bound ball of six protons (purple) and six neutrons (gold)

CHEMICAL ELEMENTS Atoms are not all the same—they can hold different numbers of protons, neutrons, and electrons. A substance made of atoms of just one type is called a chemical element, and is given an atomic number equal to the number of protons, and thus electrons, in its atoms. Examples are hydrogen, with an atomic number of 1 (all hydrogen atoms contain one proton and one electron), helium (atomic number 2), and carbon (number 6). Altogether, there are 90 naturally occurring elements. The atoms of any element are all the same size and, crucially, contain the same configuration of electrons, which is unique to that element and gives it specific chemical properties. The universe once consisted almost entirely of the lightest elements, hydrogen and helium. Most of the others, including such common ones as oxygen, carbon, and iron, have largely been created in stars and star explosions.

29

NIELS BOHR Danish physicist Niels Bohr (1885– 1962) was the first to propose that electrons in an atom move within discrete “orbits.” He suggested that these orbits have fixed energy levels and that atoms emit or absorb energy in fixed amounts (“quanta”) as electrons move between orbits. Bohr’s orbits are today called orbitals; they are substructures of electron shells.

HYDROGEN

A colorless gas at 70°F (21°C). Its atoms have just 1 proton and 1 electron in a single shell.

PROPERTIES OF ELEMENTS

Elements vary markedly in their properties, as shown by the four examples here. These properties are determined by the elements’ different atomic structures.

ALUMINUM

A solid metal at 70°F (21°C). Its atoms have 13 protons, 14 neutrons, and 13 electrons in 3 shells.

SULFUR

BROMINE

A yellow, brittle solid at 70°F (21°C). Its atoms have 16 protons, 16–18 neutrons, and 16 electrons in 3 shells.

A fuming brown liquid at 70°F (21°C). Its atoms have 35 protons, 44 or 46 neutrons, and 35 electrons in 4 shells. sodium ion

CHEMICAL COMPOUNDS

INSIDE A NEUTRON

Protons and neutrons are each made of three quarks, bound by gluons. The quarks flip between “red,” “green,” and “blue” forms, but there is always one of each color.

Electrons have a negative charge and a mass more than a thousand times smaller than a proton or neutron

I N TR OD U C TI O N

ELECTRON

Most matter in the universe consists of unbound atoms or ions of a few chemical elements, but a significant amount exists as compounds, containing atoms of more than one element joined by chemical bonds. Compounds occur in objects such as planets and asteroids, in living organisms, and in the interstellar medium. In ionic compounds, such as salts, atoms trade electrons, and the resulting charged ions are bonded by electrical forces, and arranged in a IONIC COMPOUND rigid, crystalline structure. In covalent Compounds of this compounds, such as water, the atoms are type consist of the held in structures called molecules by the ions of two or more chemical elements, sharing of electrons between them. Two typically arranged in a or more identical atoms can also combine repeating solid structure. This example is salt, sodium chloride. to form molecules of certain elements.

chloride ion

30

WHAT IS THE UNIVERSE?

STATES OF MATTER Ordinary matter exists in four states, called solid, liquid, gas, and plasma. These differ in the energy of the matter’s particles (molecules, atoms, or ions) and in the particles’ freedom to move relative to one another. Substances can transfer between states—by losing or gaining heat energy, for instance. The constituents of a solid are locked by strong bonds and can hardly move, whereas in a liquid they are bound only by weak bonds and can move freely. In a gas, the particles are bound very weakly and move with greater freedom, occasionally colliding. A gas becomes a plasma when it is so hot that collisions start to knock electrons out of its atoms. A plasma therefore consists of ions and electrons moving extremely energetically. Because stars are made of plasma, it is the most common state of ordinary matter in the universe; the gaseous state is the second most common. SOLID, LIQUID, AND GAS

On Earth, water can sometimes be found as a liquid, in solid form (ice or snow), and as a gas (water vapor), all in close proximity.

FORCES INSIDE MATTER The bonds that link the constituents of solids, liquids, gases, and plasma are based on the electromagnetic (EM) force. This force attracts particles of unlike electrical charge and repels like charges. It is one of three forces that control the small-scale structure of matter. The others are the strong nuclear force, composed of fundamental and residual parts; and the weak nuclear force or interaction. Together with a fourth force, gravity, these are the fundamental forces of nature. The EM, weak, and strong forces are mediated by force-carrier particles, neutron which belong to a group of particles called the red down quark bosons. The EM force, as well as binding atoms in solids and liquids, also holds electrons within fundamental atoms. The strong force holds together strong nuclear force protons, neutrons, and atomic nuclei. The weak force brings about radioactive decay gluon, and other nuclear interactions. the force particle

proton

PLASMA

Plasma exists naturally in stars but can also be artificially created. In a plasma ball, electricity is induced to flow from a charged metal ball through a gas to the surface of a glass sphere, creating plasma streamers. proton

+

+

RESIDUAL STRONG NUCLEAR FORCE green up quark blue down quark

FUNDAMENTAL STRONG NUCLEAR FORCE

Also known as the color force, this force binds quarks within protons and neutrons. It controls the quarks’ “color” property, and as it operates, the quarks constantly change “color” by exchanging virtual gluons (the force-carrier particles).

This force binds the protons and neutrons together in atomic nuclei. It is carried by particles called pions. Pions are generated from energy created when nucleons try to move apart. This energy arises as a byproduct of the fundamental strong force. Once generated, pions are exchanged back and forth between the nucleons, creating a binding force.

pion, the force-carrier particle residual strong nuclear force neutron

–

electromagnetic force

electrical charge

+

electron

neutrino

−

W + boson exchanged between neutron and neutrino

weak nuclear force

I N TRO D UC TI O N

neutron photon, the forcecarrier particle

down quark up quark

proton

ELECTROMAGNETIC FORCE

Within an atom, the electromagnetic (EM) force holds the electrons within the shells surrounding the nucleus. It attracts the negatively electrically charged electrons toward the positively charged nucleus and keeps electrons apart. The force carrier for the EM force is the photon.

down quark

down quark transformed into up quark

neutrino transformed into negatively charged electron neutron transformed into positively charged proton

+

down quark

WEAK INTERACTION, OR WEAK NUCLEAR FORCE

This force governs radioactive decay, among other interactions. Its forcecarrier particles are W+, W–, and Z 0 bosons. Here, a W+ boson controls the changing of a neutrino into an electron and the transformation of a down quark into an up quark, converting a neutron into a proton.

up quark

STEVEN WEINBERG American physicist Steven Weinberg (b. 1933) is best known for his theory that two of the fundamental forces—the weak interaction and the electromagnetic force—are unified, or work in an identical way, at extremely high energy levels, such as those existing just after the Big Bang (see p.48). Weinberg’s so-called electroweak theory was confirmed by particle accelerator experiments in 1973. He and his colleagues received the 1979 Nobel prize for physics.

MATTER

PARTICLE PHYSICS For some decades, physicists have directed research toward a better understanding of matter and the four fundamental forces. Part of the purpose has been to clarify what happened in the early universe, shortly after the Big Bang. Research is centered on smashing particles together in devices called particle accelerators. These experiments have identified hundreds of different particles (most of them highly unstable), which differ in their masses, electric charges, other properties such as “spin,” and in the fundamental forces they are subject to. Known particles, and their interactions, are currently explained by a theory called the standard model of particle physics. This explains the properties of most of the particles (see table, right). One exception is the graviton, a hypothetical particle thought to carry the force of gravity. The graviton does not fit into the scheme, because the best theory of gravity (general relativity, see pp.42–43) is incompatible with aspects of the standard model. New theories such as string theory (see panel, below) attempt to unite gravity with particle physics. SPRAY OF PARTICLES

This image from a detector within a particle accelerator shows a spray of light particles shooting to the right, following collision of two higher-mass particles on the left.

hydrogen nucleus (single proton) hydrogen nuclei fuse, and one is converted into a neutron neutrino hydrogen nucleus

positron

deuterium nucleus (1 proton, 1 neutron) helium-3 nucleus (2 protons, 1 neutron)

gamma-ray photon addition of another proton releases energy

fusion of helium-3 nuclei forms stable helium-4 and releases excess protons

helium-4 nucleus (2 protons, 2 neutrons)

CLASSIFICATION OF PARTICLES Physicists distinguish composite particles, which have an internal structure, from fundamental particles, which do not. They also divide particles into fermions and bosons. Fermions (leptons, quarks, and baryons) are the building blocks of matter. Bosons (gauge bosons and mesons) are primarily force-carrier particles. FUNDAMENTAL PARTICLES

COMPOSITE PARTICLES

Leptons and quarks form matter, while gauge bosons carry forces. Quarks feel the strong nuclear force, but leptons do not.

Also known as hadrons, these are composed of quarks, antiquarks, or both, bound by gluons.

LEPTONS

QUARKS

electron, charge –1 neutrino, charge 0

Six different leptons exist, but the 2 above are the only stable ones and are those that occur in ordinary matter.

up, charge +2⁄3

There are 6 “flavors” of quark, but only 2 occur in ordinary matter: “up” and “down”. Each can exist in any of 3 “colors.”

GAUGE BOSONS

These are force-carrier particles. Some shown are hypothetical. W + intermediate vector boson

photon

BARYONS

Relatively large-mass particles containing 3 quarks.

down, charge –1⁄3

gluon

proton, 1 down and 2 up quarks, charge +1 neutron, 1 up and 2 down quarks, charge 0 MESONS

Particles containing a quark and an antiquark. positive pion, 1 up quark, 1 anti-down quark, charge +1

X-boson (hypothetical)

graviton (hypothetical)

Higgs boson (hypothetical)

Hundreds of other baryons and mesons exist.

ANTIPARTICLES

EXOTIC PARTICLES

Most particles have an antimatter equivalent that has the same mass, but whose charge and other properties are opposite.

Further particles have been hypothesized that do not have a place in this particle classification. They include magnetic monopoles and WIMPs (weakly interacting massive particles).

positron (antielectron), charge +1

anti-up quarks, charge –2⁄3

antiproton,1 antidown and 2 anti-up quarks, charge –1

antineutrino

antineutron, 1 antiup and 2 anti-down quarks, charge 0

NUCLEAR FISSION AND FUSION Twentieth-century physicists learned that atomic nuclei are not immutable but can break up or join together. In nature, unstable atomic nuclei can spontaneously disassemble, giving off particles and energy, measured as radioactivity. Similarly, in the artificial process of nuclear fission, large nuclei are intentionally split into smaller parts, with huge energy release. On a cosmic scale, a more important phenomenon is nuclear fusion. In this process, atomic nuclei join, forming a larger nucleus and releasing energy. Fusion powers stars and has created the atoms of all chemical elements heavier than beryllium. The most common fusion reaction in stars joins hydrogen nuclei (protons) into helium nuclei. In this and other fusion reactions, the products of the reaction have a slightly lower mass than the combined mass of the reactants. The lost mass converts into huge amounts of energy, in accordance with Einstein’s famous equation E=mc2 that links energy (E), mass (m), and the speed of light (c) (see p.41).

FUSION REACTION IN THE SUN

THE HEAT OF FUSION

In stars the size of the Sun or smaller, the dominant energy-producing fusion process is called the proton– proton chain. This chain of high-energy collisions fuses hydrogen nuclei (free protons), via several intermediate stages, into helium-4 nuclei. Energy is released in the form of gamma-ray photons and in the movement energy of the helium nuclei. Positrons and neutrinos are also produced.

All solar energy comes from nuclear fusion in the Sun’s core. The energy gradually migrates to the Sun’s surface and into space through heat transfer by convection, conduction, and radiation.

EXPLORING SPACE

STRING THEORY For decades, physicists have sought a “theory of everything” (see Quantum gravity, p.43) that will unify the four fundamental forces of nature and provide an underlying scheme for how particles are constructed. A leading contender is string theory, which proposes that each fundamental particle consists of a tiny vibrating filament called a string. The vibrational modes, or frequencies, of these strings lend particles their varied properties. Although it sounds bizarre, many leading physicists are enthusiastic adherents of string theory. LOW-FREQUENCY STRING

VIBRATING STRINGS

A string is closed, like a loop, or open, like a hair. The two closed strings shown here are vibrating at different resonant frequencies, just as the strings on a guitar have rates at which they prefer to vibrate.

HIGH-FREQUENCY STRING

I N TR OD U CT I ON

hydrogen nucleus

hydrogen nucleus

31

NEUTRINO OBSERVATORY

High-energy processes in the Universe produce neutrinos—fast-moving particles that rarely interact with matter. To detect them, scientists created the IceCube Neutrino Observatory in Antarctica. Eighty-six holes drilled in the ice contain over 5,000 optical sensors. In the dark, clear ice the sensors record faint flashes of light as neutrinos crash into the ice molecules.

34

WHAT IS THE UNIVERSE?

RADIATION RADIATION IS ENERGY IN THE FORM

28–31 Matter Light and gravity 42 Beyond visible light 91 Observing from space 94–95 Stars 232–33

electric field strength

of waves or particles that are emitted from a source and can travel through space and some types of matter. Electromagnetic (EM) radiation includes light, X-rays, and infrared radiation. Particulate radiation consists of fast-moving charged particles such as cosmic rays and particles emitted in radioactive decay. EM radiation is vastly more significant in astronomy.

amplitude

ELECTROMAGNETIC RADIATION

magnetic field strength

wavelength

HOW WAVES TRAVEL

An EM wave consists of oscillating electrical and magnetic fields arranged perpendicular to each other, and carrying energy forward.

Energy in the form of EM radiation is one of the two main components of the universe, the other being matter (see p.28). This type of radiation is produced by the motion of electrically charged particles, such as electrons. A moving charge gives rise to a magnetic field. If the motion is constant, then the magnetic field varies and in turn produces an electric field. By interacting with each other, the two fields sustain one another and move through space, transferring energy. As well as visible light, EM radiation includes radio waves, microwaves, infrared (heat) radiation, ultraviolet radiation, X-rays, and gamma rays. All these phenomena travel through space at the same speed—called the velocity of light. This speed is very nearly 186,000 miles (300,000 km) per second or 670 million mph (1 billion km/h).

WAVELIKE BEHAVIOR In most situations, EM radiation acts as a wave—a disturbance moving energy from one place to another. It has properties such as wavelength (the distance between two successive peaks of the wave) and frequency (the number of waves passing a given point each second). This wavelike nature is shown by experiments such as the double-slit test (see below), in which light waves diffract (spread out) after passing through a slit and also interfere with each other as their peaks and INTERFERING WAVES The slit experiment troughs overlap. The forms is analogous to of EM radiation differ only disturbing two points in wavelength, but this affects on the surface of a other properties, such as liquid. The ripples penetrating power and ability interfere to corrugate the liquid’s surface. to ionize atoms (see p.28). light waves along red paths combine to cast bright band on screen

PARTICLE-LIKE BEHAVIOR EM radiation behaves mainly like a wave, but it can also be considered to consist of tiny packages or “quanta” of energy called photons. Photons have no mass but carry a fixed amount of energy. The energy in a photon depends on its wavelength— the shorter the wavelength, the more energetic the photon. For example, photons of blue (shortwavelength) light are more energetic than photons of red (long-wavelength) light. A classic demonstration of light’s particle-like properties is provided by a phenomenon called the photoelectric effect (see below). If a blue light shines on a metal surface, it causes electrons to be ejected from the metal, whereas even a very bright red light has no such effect. ultra-high-energy ultraviolet photon

pattern of light falling on screen low-energy photon of red light

low-energy electron

slit

INTRODUCTION

high-energy photon of blue light

light source

electron ejected at higher energy

gold foil

SLIT EXPERIMENT

If light shines on a card containing two slits, diffraction spreads the light waves out like ripples emanating in arcs from each slit. The two wave trains then interfere to produce a light and dark pattern on the screen.

light waves forming interference pattern

RED LIGHT

BLUE LIGHT

ULTRAVIOLET LIGHT

When red light shines on a metal surface, no electrons are ejected, even if the light is intensely bright.

Blue light shining on the same surface causes electrons to be ejected, because the blue photons are more energetic.

Shining ultraviolet light on the metal surface causes electrons to be ejected at very high energy.

RADIATION

35

ANALYZING LIGHT The radiation output of celestial objects is a mixture of wavelengths. When passed through a prism, the light is split into its component wavelengths, giving a record called a spectrum. A star’s spectrum usually contains dark lines called absorption lines, caused by photons being absorbed at certain wavelengths by atoms in the star’s atmosphere. They can be used to establish what chemical elements are present. The spectrum of a nebula can also reveal its composition. When heated by radiation from a nearby star, its atoms emit their own light. The resulting spectrum, called an emission spectrum, consists of a series of radiating star absorption by bright lines characteristic of nebula different elements. radiation remaining after absorption prism

emission by heated gas

SPECTRUM WITH AN ABSORPTION LINE

When a star is viewed through a cooler gas, dark lines appear in the spectrum. These are caused by atoms in the gas absorbing energy at specific wavelengths.

direct radiation from star

EMISSION NEBULA

This nebula glows as its gas is heated by nearby stars. The emitted light consists of photons of a few specific wavelengths. These photons were emitted by the gas’s atoms as their electrons settled to lower energy states.

LOUIS DE BROGLIE The French physicist Louis de Broglie (1892–1987) received the Nobel prize in 1929. He found that particles of matter, such as electrons, have wavelike properties. The dual nature of matter and light (each has both particle-like and wavelike properties) is called waveparticle duality.

The spectrum of radiation received by an observer shifts if the source of the radiation is moving relative to the observer—and celestial objects are always moving. Astronomers can detect the shifts by measuring the position of spectral lines, which occur at characteristic places. Observers watching an object moving away see its spectral lines shifted toward longer wavelengths (a red shift). For an approaching object, the lines are shifted to the shorter wavelengths (a blue shift). The greater the relative velocity between source and observer, the greater the shift. Distant wavefront of galaxies show large red shifts, emitted radiation indicating they are receding at enormous speeds; these are called cosmological red shifts.

OBSERVER 1 RED-SHIFTED SPECTRUM LINE

very hot blue star

RADIATION FROM HOT OBJECTS

Not only is the total radiation greater from hotter objects, but the wavelength of peak intensity is also shorter (toward the blue end of the light spectrum). Astronomers can calculate the temperature of stars by measuring the peak of the star’s spectrum.

hot yellow star, such as the Sun

cooler red star

Earth galaxy receding from observer 1 and approaching observer 2 WAVELENGTH

wavefronts bunched up

OBSERVER 2

BLUE-SHIFTED SPECTRUM LINE

INTRODUCTION

Shifts occur because of a phenomenon called the Doppler effect. The wavefronts of light from a receding object are stretched out, increasing their wavelength, while those of an approaching object are squashed up.

A hot, dense gas such as a star produces a continuous light spectrum from its surface, with all different light wavelengths (colors) represented.

RED SHIFT AND BLUE SHIFT

wavefronts spread out

SHIFTING WAVELENGTHS

CONTINUOUS SPECTRUM

A gas that has been heated by energy from a local star reemits radiation at specific wavelengths. When viewed obliquely, this produces an emission-line spectrum.

INTENSITY

SPECTRUM WITH AN EMISSION LINE

36

WHAT IS THE UNIVERSE?

ACROSS THE SPECTRUM Celestial objects can emit radiation across the EM spectrum, from radio waves through visible light to gamma rays. Some complex objects, such as galaxies and supernova remnants, shine at nearly all these wavelengths. Cool objects tend to radiate photons with less energy and are therefore only visible at longer wavelengths. Toward the gamma-ray end of the spectrum, photons are increasingly powerful. High-energy X-rays and gamma rays originate only from extremely hot sources, such as the gas of galaxy clusters (see p.327) or violent events, such as the swallowing of matter by black holes (see p.267). To detect all this radiation and form images, astronomers need a range of instruments—each type of radiation has different properties and must be collected and focused in a particular way. Radiation at many wavelengths does not penetrate to Earth’s surface, and is detectable only by orbiting observatories above the atmosphere. RADIO WAVES TELESCOPE ARRAY Radio waves can be many meters long. To create sharp images from such long waves, astronomers collect and focus them using telescopes with huge dish antennae. They might use a single dish or an entire array. The Very Large Array (right), in New Mexico, is the world’s largest array. It consists of 27 dishes, each 82 ft (25 m) across, moving on a Y-shaped rail network. Their data combines to form a single, fine-detailed image, the dishes effectively forming one giant, 16-mile (27-km) antenna.

primary reflector dish

parabolic dish reflects all incoming radio waves to the subreflector receiver

Sun shield

subreflector focuses the radio waves onto receiver

MICROWAVES SPACE PROBE Most microwaves are absorbed by Earth’s atmosphere, so microwave observatories must be placed in space. Launched in 2001, the Wilkinson Microwave Anisotropy Probe (WMAP, above) is a NASA spacecraft with a goal to map the cosmic microwave background radiation (see p.54) across the whole sky. This is the oldest electromagnetic radiation in the universe, released soon after the Big Bang. The probe was placed in a stable orbit around the Sun 900,000 miles (1.5 million km) from Earth.

INFRARED MOUNTAINTOP TELESCOPE Little infrared radiation from space reaches sea level on Earth, but some penetrates down to the height of mountaintops. Some infrared telescopes, such as NASA’s Spitzer Space Telescope (see p.247), have been launched into space, but most infrared astronomy is conducted from mountain observatories. This one, the United Kingdom Infrared Telescope (UKIRT) is at 13,760 ft (4,194 m) in Hawaii. Like optical telescopes, it uses mirrors to collect and focus the radiation. With a 12.5-ft (3.8-m) mirror, UKIRT achieves great brightness and resolution. It can pick up dim galaxies, brown dwarfs, nebulae, and interstellar molecules glowing in the infrared, and it can peer into starforming nebulae to image the young stars shining within.

red denotes a fractionally higher temperature

blue denotes a slightly lower temperature

RADIO WAVES GALAXY In this map of the Andromeda Galaxy produced by a radio telescope, red and yellow indicate the highest-intensity radio-wave emissions. To produce such an image, a radio dish must scan an area of sky. As it points at each location in the sky in turn, the telescope gradually builds a picture by recording the radio intensity at each location. The resolution is low because radio waves are so long. Radio emissions are produced by hydrogen clouds in galaxies, or by synchrotron radiation from active galaxies (see p.320) and black holes (see p.267).

INFRARED MICROWAVES UNIVERSE

GALACTIC CENTER

The lack of microwave sources in the nearby universe is fortunate, because it reduces difficulties in observing the cosmic background radiation, which reaches Earth at microwave wavelengths. The pattern of microwaves from the whole sky, as measured by WMAP, is here projected onto two hemispheres.

This infrared image penetrates to the central region of the Milky Way galaxy, which in visible light is hidden behind thick clouds of dust. The core of the galaxy is at upper left. The reddening of the stars in that area and along the galactic plane is caused by dust scattering.

RADIO WAVES

HEIGHT IN EARTH’S ATMOSPHERE

I N TRO D U CT I ON

60 miles (100 km)

30 miles (50 km)

0

INFRARED

MICROWAVES

WAVELENGTH 100 m

1 km

opaque atmosphere at long radio wavelengths

10 m

1m

10 cm

ATMOSPHERIC ABSORPTION Only certain types of EM radiation—visible light and some radio waves—can pass through Earth’s atmosphere. Others are absorbed to varying extents, and can only be detected from space or at high altitudes. Gray areas transparent indicate the altitude at which atmosphere at shorter different wavelengths are radio wavelengths absorbed.

1 cm

1 mm

100 μm

RADIO WINDOW Radiation with wavelengths between 1 cm and 11 m (0.4 in–36 ft) passes readily through the atmosphere. This part of the spectrum, which includes some radio waves and some microwaves, is called the “radio window.” opaque atmosphere

10 μm

RADIATION

37

EXPLORING SPACE

IMAGES FROM INVISIBLE RADIATION Astronomers have developed telescopes that can gather information from EM radiation other than visible light, but they still face a problem of how to visualize the invisible. The 1 High-energy 2 Low-energy 3 Image in infrared most popular technique uses (short-wavelength) (longer-wavelength) radiation, taken by computers to create “falseX-ray image from X-ray image from the Spitzer Space color” images—pictures that Chandra Observatory. Chandra Observatory. Telescope. show the object in particular (see p.273) show radiation in visible light, wavelengths of radiation, sometimes infrared, and two different wavelengths of color-coded, but often just using X-rays, revealing the temperature of different varying intensities of a single color. regions and the overall structure. These images of Kepler’s Supernova solar array

solar panel

telescope body

COMBINED IMAGE

The false-color images are combined with a Hubble image of the remnant in visible light.

nested grazing incidence mirrors sunshade door

VISIBLE LIGHT OPTICAL TELESCOPE Optical telescopes with the largest mirrors achieve the brightest, sharpest images and the greatest power (see p.82). They range from those of amateur astronomers, such as this example with an 8.5-in (21.5-cm) mirror, to those of large observatories, with mirrors up to 33 ft (10 m) wide. Other telescopes include the 98-ft (30-m) Thirty Meter Telescope and the 128-ft (39-m) European Extremely Large Telescope (E-ELT).

X-RAYS ORBITING OBSERVATORY

ULTRAVIOLET ORBITING OBSERVATORY

NASA’s Extreme Ultraviolet Explorer satellite (above) surveyed sources of extreme (very-short wavelength) ultraviolet radiation during the 1990s. Ultraviolet light originates from hot sources such as white dwarfs, neutron stars, and Seyfert galaxies (see p.320).

X-rays are highly energetic and so powerful that they pass through conventional mirrors. To focus X-rays, telescopes such as the Chandra X-ray Observatory (above) use a nest of curved “grazing incidence” mirrors of polished metal. X-rays glance off these mirrors, like ricocheting bullets, toward the focal point.

GAMMA-RAY ORBITING TELESCOPE

Gamma rays are the most energetic EM waves, emitted by the most violent cosmic events. The Fermi Gamma-Ray Space Telescope (above) was launched in 2008 to study gamma rays from phenomena such as supernovae, black holes, pulsars, and gamma-ray bursts. point source Milky Way

GAMMA-RAY SKY Gamma rays are too powerful to focus, so sharp images are impossible. This This image of spiral galaxy M74 is a composite The orange-pink regions in this Chandra view of the sky shows the Milky Way The spiral galaxy M90, which lies 30 million of visible light and ultraviolet images. The as a bright band. Point sources may be light-years away, is shown here as it appears Observatory image of two colliding galaxies high-energy ultraviolet emission is in blue neutron stars or hypernovae (see p.55). to human eyes through a large telescope. This (called the Antennae, see p.317) are X-rayand white and picks out extremely hot, The image comes from the Energetic galaxy is similar in size to the Milky Way. The emitting “superbubbles” of hot gas. The young stars in the spiral arms and Gamma Ray Experiment Telescope image was taken at Kitt Peak National point X-ray sources (bright spots) are in the galactic nucleus. (EGRET) on the Compton Observatory. Observatory in Arizona. black holes and neutron stars.

ULTRAVIOLET GALAXY

VISIBLE LIGHT GALAXY

VISIBLE 1 μm transparent atmosphere

ULTRAVIOLET 100 nm

X-RAY GALAXY

X-RAYS 10 nm

0.1 nm

0.01 nm

opaque atmosphere

0.001 nm

0.0001 nm

0.00001 nm

I N TR OD U CT I ON

OPTICAL WINDOW Wavelengths of radiation between 300 and 1,100 nm (nanometers) pass easily through the atmosphere (the visible light spectrum extends from 400 to 700 nanometers).

GAMMA RAYS 1 nm

38

WHAT IS THE UNIVERSE?

GRAVITY, MOTION, AND ORBITS GRAVITY IS THE ATTRACTIVE FORCE

that exists between every object in the universe, the force that both holds stars and galaxies Planetary motion 68–69 together and causes a pin to drop. Gravity is weaker than nature’s Observing from space 94–95 other fundamental forces, but because it acts over great distances, The family of the Sun 102–103 and between all bodies possessing mass, it has played a major part in shaping the universe. Gravity is also crucial in determining orbits and creating phenomena such as planetary rings and black holes. Space and time 40–41

The disk- and ringlike structures common in celestial objects are maintained by gravity. Examples include Saturn’s rings (pictured), spiral galaxies, and the disks around black holes. Every particle in Saturn’s rings is held in orbit through gravitational interactions with billions of other particles and with Saturn itself.

NEWTONIAN GRAVITY

NEWTON’S LAWS OF MOTION

The scientific study of gravity began with Galileo Galilei’s demonstration, in about 1590, that objects of different weight fall to the ground at exactly the same, accelerating rate. In 1665 or 1666, Isaac Newton realized that whatever force causes objects to fall might extend into space and be responsible for holding the Moon in its orbit. By analyzing the motions of several heavenly objects, Newton formulated his law of universal gravitation. It stated that every body in the universe exerts an attractive force (gravity) on every other body and described how this force varies with the masses of the bodies and their separation. To this day, Newton’s law remains applicable for understanding and predicting the movements of most astronomical objects.

From his studies of gravity and the motions of heavenly bodies, and again extending concepts first developed by Galileo, Newton formulated his three laws of motion. Before Galileo and Newton, people thought that an object in motion could continue moving only if a force acted on it. In his first law of motion, Newton contradicted this idea: he stated that an object remains in uniform motion or at rest unless a net force acts on it (a net force is the sum of all forces acting on an object). Newton’s second law states that a net force acting on an object causes it to accelerate (change its velocity) at a rate that is directly proportional to the magnitude of the force. It also states that the smaller the mass of an object, the higher the acceleration it experiences for a given force. Newton’s third law states that for every action there is an equal and opposite reaction—for example, Earth’s gravitational pull on the Moon is matched by the pull of the Moon on Earth.

F

FIRST LAW OF MOTION

1 Two bodies, each of mass m, attract each other with force F

F m

m

The first law states that an object remains in a state of rest or moves at a constant speed in a straight line unless acted on by a net force.

distance = 1 4F

4F

2 Doubling the mass of each 2m body, while maintaining their separation, quadruples the gravitational force to 4F

2m

2m

F

F 2m

distance = 2 3 Doubling the separation between the bodies reduces the force by a factor of 4, back to F

ISAAC NEWTON The English mathematician and physicist Isaac Newton (1642–1727) was one of the greatest-ever scientific intellects. As well as his discoveries in the fields of gravity and motion, he co-discovered the mathematical technique of calculus. In 1705, Newton became the first scientist to be knighted for his work.

constant, uniform motion

altered motion

force

SECOND LAW OF MOTION

distance = 1

I N TR OD UC TI O N

DISKS AND RINGS

When an object of low mass and one of greater mass are subjected to a force of the same magnitude, the low-mass object accelerates at a higher rate.

MASS AND DISTANCE

THIRD LAW OF MOTION

Any two bodies are attracted by a force of gravity proportional to the mass of one multiplied by the mass of the other. The force is also inversely proportional to the square of their separation.

To every action there is an equal and opposite reaction. The forward thrust of a rocket is a reaction to the backward blast of combusted fuel.

high mass, slow acceleration

action: backward blast of fuel

WEIGHT AND FREE FALL The size of the gravitational force acting on an object is called its weight. An object’s rest mass (measured in pounds or kilograms) is constant, while its weight (measured in newtons) varies according to the local strength of gravity. A mass of 2.2 lb (1 kg) weighs 9.8 newtons on Earth, but only 1.65 newtons on the Moon. Weight can be measured, and the feeling of weight experienced, only when the gravity producing it is resisted by a second, opposing, force. A person standing on Earth feels weight not so much from the pull of gravity as from the opposing push of the ground on his or her feet. In contrast, a person orbiting Earth is actually falling toward Earth under gravity. WEIGHTLESSNESS Astronauts in training must Such a person is in “free fall” frequently experience apparent and experiences apparent weightlessness. Here, a plane weightlessness. This is due not to is plunging sharply from high lack of gravity but to the absence altitude, putting the trainee of a force opposing gravity. astronauts inside into free fall.

reaction

low mass, high acceleration

39

COMMON CENTER OF MASS

smaller body (smaller star or planet)

SHAPES OF ORBITS

When one object is in orbit around another object of higher mass, it is in free fall toward the larger body. It experiences a constant gravitational acceleration toward the larger object that deflects what would otherwise be its straightline motion into a curved trajectory. The direction of its motion, and the direction of acceleration both constantly change, producing its curved path. All closed orbits in nature have the shape of an ellipse (a stretched circle). The degree to which an ellipse varies from a perfect circle is called its eccentricity. Many solar system orbits (such as the Moon’s around Earth) are not very eccentric—that is, they are almost circular. Others, such as Pluto’s orbit around the Sun, are much more eccentric and highly elongated. Some celestial bodies follow open, non-returning orbits, along curves with shapes called parabolas and hyperbolas. path planet would take from point B if there was no gravity path planet would take from point A if there was no gravity C B

planet following elliptical orbit around star A

acceleration toward star due to pull of gravity

pivot: center of rotation of both bodies

common center of mass

In an orbital system of two bodies, the smaller body does not simply orbit the larger one. Instead, both revolve around the joint center of mass. In the Earth–Moon system, this point is located deep inside Earth. For two bodies of more equal mass, it is located in space between the two objects.

smaller orbit of larger body larger orbit of smaller body larger body (massive star)

COMPACT, ROTATING BODIES Stars, pulsars, galaxies, and planets all rotate, governed by the law of conservation of angular momentum. An object’s angular momentum is related to its rotational energy, which depends on the distribution of mass in the object and on how fast it spins. The angular momentum of any rotating object stays constant, so if gravity causes the object to contract, its spin rate increases to make up for the redistribution of mass. Compact, fast-rotating objects therefore tend to form from diffuse, slowly-rotating ones. ANGULAR MOMENTUM

apoapsis (point at which orbiting object is farthest from the orbit’s focus)

comet from deep space star

focus of orbits

hyperbolic path

ORBITING BODIES

Shown here are two elliptical orbits of different eccentricities and a hyperbolic path. Any orbit results from the combined effect of an object’s tendency to move at constant speed in a straight line and the gravitational pull of the body it orbits.

planet following a more eccentric (elongated) elliptical orbit

paths of skater’s limbs as she spins fast, with a compact body shape paths of skater’s limbs as she spins slowly, with a less compact body shape

When an ice skater draws her limbs in, her spin rate soars. Similarly, a rotating cloud of gas spins faster as it contracts.

I N TR OD U C TI O N

periapsis (point of closest approach)

40

WHAT IS THE UNIVERSE?

SPACE AND TIME MOST PEOPLE SHARE SOME COMMON-SENSE NOTIONS

about the world. One is that time passes at the same rate for everyone. 38–39 Gravity, motion, and orbits Another is that the length of a rigid object does not change. path of Expanding space 44–45 1’s In fact, such ideas, which once formed a bedrock for the laws Observer The family of the Sun 102–103 ball, as seen by Observer 2 of physics, are an illusion: they apply only to the restricted range of situations with which people are most familiar. In fact, time and space are not absolute, but stretch and warp depending on relative viewpoint. What is more, the presence of matter distorts both space and time to produce the force of gravity. 34–37 Radiation

PROBLEMS IN NEWTON’S UNIVERSE Problems with the Newtonian view of space and time (see p.38) first surfaced toward the end of the 19th century. Up to that time, scientists assumed that the positions and motions of objects in space should all be measurable relative to some non-moving, absolute “frame of reference,” which they thought was filled with an invisible medium called “the ether.” However, in 1887, an experiment to measure Earth’s motion through this ether, by detecting variations in the velocity of light sent through it in different directions, produced some unexpected results. First, it failed to confirm the existence of the ether. Second, it indicated that light always travels at the same speed relative to an observer, whatever that observer’s own movements. This finding suggested that light does not follow the same rules of relative motion that govern everyday objects such as cars and bullets. If a person were to chase a bullet at half of the bullet’s speed, the rate at which the bullet moved away from him or her would CONSTANT SPEED OF LIGHT halve. However, if a person were to chase a Light leaves both the ceiling lights and the headlights of light wave at half the speed of light, the wave the moving cars at the same speed relative to its source. would continue moving away from him Paradoxically, light from both sources reaches an observer standing in the tunnel at, again, exactly the same speed. or her at exactly the same velocity. Observer 1

I NT RO DU C TI ON

ALBERT EINSTEIN The work of German-born mathematician and physicist Albert Einstein made him the most famous scientist of the 20th century. Although he won the Nobel prize for his work on the particle-like properties of light (see p.34), he is more famous for his theories of special relativity (1905) and general relativity (1915). These theories introduced a revolutionary new way of thinking about space, time, mass, energy, and gravity.

SPECIAL RELATIVITY

path of Observer 1’s ball, as seen by Observer 1

In 1905, Albert Einstein rejected the idea that there is any absolute or “preferred” frame of reference in the universe. In other words, everything is relative. He also rejected the idea that time is absolute, suggesting that VIEWPOINT ONE it need not pass at the same rate everywhere. To replace the From Observer 1’s point of view, old ideas, he formed the special theory of relativity, called the green ball within his or her “special” because it is restricted to frames of reference in own frame of reference travels constant, unchanging motion (because they are not being up and down. If Observer 1 looks accelerated by a force, see p.38). He based the entire theory on across at the red ball in a frame two principles. The first principle, called the principle of of reference in relative motion, the ball seems to follow an arc. relativity, states that the same laws of physics apply equally in all constantly moving frames of reference. The second principle states that the speed of light is constant and independent of the motion of the MOVING FRAMES OF REFERENCE observer or source of light. Einstein recognized that this second principle Here we see two travelers—effectively two moving reference frames—passing each other. conflicts with accepted notions about Each tosses a ball up. By the principle of relativity, how velocities add together; further, the laws of physics apply in each reference frame, so each traveler observes the behavior of the that combining it with the first principle seems to lead to perplexing, two balls as predicted by those laws. Although direction of the two travelers see different motions for each Observer 1’s nonintuitive results. He perceived, ball, neither traveler’s point of view is superior to motion however, that human intuition about the other’s—both are equally valid, and there is time and space could be wrong. no preferred frame of reference.

direction of Observer 2’s motion

SPACE AND TIME

path of Observer 2’s ball, as seen by Observer 2

EFFECTS OF SPECIAL RELATIVITY The results that flow from the principles of special relativity are remarkable. Using thought experiments, Einstein showed that for the speed of light to be the same in all reference frames, measures of space and time in one frame must be transformed to those in another. These transformations show that when an object moves at high speed relative to an observer, the observer sees less of its length—an effect called Lorentz contraction. Also, time for such an object appears to run more slowly—an effect called time dilation. So measurements of time and space vary between moving reference frames. Einstein also showed that an object gains mass when its energy increases and loses it when its energy decreases. This led him to realize that mass and energy have an equivalence, which he expressed in the famous equation E (energy) = m (mass) x c2 (the speed of light squared).

spacecraft traveling at 90 percent of the speed of light relative to Earth

10 MINUTES ELAPSED observer on Earth

20 MINUTES ELAPSED

10 MINUTES ELAPSED

MASS IS ENERGY

To Einstein’s ultimate dismay, one of the first applications of his equation E=mc² was the development of atomic bombs. In such bombs, the loss of tiny amounts of mass in nuclear reactions releases vast amounts of energy.

SYMMETRICAL EFFECTS

Relativistic effects occur symmetrically, because there is no absolute frame of reference. For the spacecraft pilot, time on Earth passes more slowly. More than 20 minutes pass on the spacecraft while the pilot watches a clock advance only 10 minutes on Earth.

MEASURING STRETCHED TIME

passage through space-time of an object that stays at the same point in space

TIME

cone of future space-time

SPACE-TIME A further implication of special relativity is that space and time are closely linked. When two events occur in separate places, the space between them is ambiguous, because observers traveling at different SPACE velocities measure different distances. object in the present each 2-D plane The time passing between the events at its starting point represents 3-D space in space also depends on each observer’s motion. However, a mathematical method can be devised FOUR DIMENSIONS for measuring the separation of events, involving a In this representation of spacecombination of space and time, that gives values that all time, time moves upward into observers can agree on. This led to the idea that events the future, while the three spatial dimensions are reduced in the universe should no longer be described in three to two-dimensional planes. The spatial dimensions, but rather in a four-dimensional cone represents the effective world, incorporating time, called space-time. In this limits of space-time for any system, the separation between any two events is object—its boundary is described by a value called a space-time interval. defined by the speed of light.

I N TR OD U CT I ON

Special relativity’s prediction that time can stretch has been proved to be true by mounting atomic clocks in jet airliners and monitoring their timekeeping compared with Earth-bound clocks. Here, American physicist Harold Lyons explains an early experiment of this type, with the help of a graphic. Relativistic time dilation has some practical consequences. The atomic clocks in global positioning system (GPS) satellites run about 7.2 microseconds a day slower than Earth-bound atomic clocks, so their data must be adjusted to maintain accuracy.

light would move through space-time along the side of the cone

passage through space-time of an object moving from place to place

SP AC E

EXPLORING SPACE

observer on spacecraft

20 MINUTES ELAPSED

Observer 2

To Observer 2, the red ball within his or her own reference frame appears to move vertically. The green ball, which is in another frame of reference in relative motion, seems to follow an arc-shaped path.

TIME DILATION

Special relativity predicts that an Earthbound observer sees time slow down onboard a spacecraft traveling at close to the speed of light relative to Earth. At 90 percent of light-speed, the passage of time is halved—a clock on the spaceship advances only 10 minutes while more than 20 minutes pass on Earth.

path of Observer 2’s ball, as seen by Observer 1

VIEWPOINT TWO

41

42

WHAT IS THE UNIVERSE?

ACCELERATING MOTION

apparent position of galaxy to observers on Earth, who assume light has traveled in a straight line

Having completed his study of relativity in the special case of reference frames in uniform motion (inertial reference frames), Einstein turned his attention to changing, or accelerated motion. In particular, he examined the link between gravity and acceleration. This led him to formulate a proposition called the principle of equivalence, which describes gravity and acceleration as different perspectives of the same thing. Specifically, Einstein stated that it was impossible for any experiment to tell the difference between being at rest in a uniform gravitational field and being accelerated. He illustrated this idea using thought experiments involving scientists sealed into boxes under various conditions of acceleration and gravity. Starting from the principle of equivalence, by 1915 Einstein had gone on to develop his most complex sealed box undergoing and major masterpiece, the general uniform acceleration theory of relativity, which provided a new description of gravity. person is weighed down

true position of galaxy

sealed box in a uniform gravitational field, caused by planet’s gravity ball falls to the floor

rocket engine accelerates box and imparts the same force as the planet’s gravity ball falls to the floor

person is weighed down planet’s mass creates gravitational field

I NT RO DU C TI ON

LIGHT AND GRAVITY

GRAVITY AND ACCELERATION FEEL THE SAME

A person in a sealed box at rest on the surface of a planet with a strong gravitational field, and a person within a similar box in deep space that is being accelerated by a rocket, could not distinguish between the two situations.

orbiting planet follows elliptical path because space-time is curved in the vicinity of the Sun two-dimensional rubber sheet represents four-dimensional space-time—dents in the sheet represent distortions of space-time sealed box undergoing uniform acceleration upward

By visualizing experiments in accelerating reference frames and using the principle of equivalence to transpose them to gravitational situations, Einstein postulated that light, despite having no mass, should follow a curved path in a gravitational field. Although he had no direct evidence that this was true, he convinced himself that it must be (by 1919, it had been shown to be true by astronomical sealed box in a uniform observations). Developing the idea further, Einstein theorized gravitational field, caused that gravitational effects might be caused by large masses or by planet’s gravity concentrations of energy causing a local distortion in the shape of four-dimensional space-time—that is, that gravity might be a purely light source geometrical consequence of the effect of mass on space-time. If so, light curves around a large beam of light mass because of the warping of curves through gravitational field space-time caused by the mass. Similarly, a planet in orbit around a star, such as the Earth around the Sun, follows a curved trajectory not because of a pull of the star on the planet, but because space-time is warped in the vicinity of the star, and the shortest path for the planet to take through this distorted massive planet creates region of space-time is a curved one. gravitational field

beam of light bends downward

THOUGHT EXPERIMENT WITH LIGHT

If a light beam is fired across a box that is accelerating upward, within the box the light would appear to curve downward. By the equivalence principle, in an identical experiment carried out on a box in a gravitational field, a light ray should follow the same downward curve.

43

GENERAL RELATIVITY AT WORK

DENTED SPACE-TIME

Space-time can be visualized as a rubber sheet in which massive objects make dents. In this view, planets orbit the Sun because they roll around the dent it produces. Similarly, light passing by a massive object has its straightline path deflected by following the local curvature of space-time. Remember, however, that it is 4-dimensional space-time, not just space, that is warped. white dwarf star

object with large mass

Einstein encapsulated his theory of how mass distorts space-time in his set of “field equations.” Physicists have used these equations to find that it is in the strongest gravitational fields—where massive, dense objects distort space-time most strongly—that reality departs farthest from that predicted by Newton (see p.38). For instance, Mercury is so close to the Sun that it always moves in a strong gravitational field (or in strongly curved space-time). Its orbit is distorted in a way that Newton could not account for, but which general relativity explains perfectly (see p.110). General relativity also provides a framework for models of the universe’s structure, development, and eventual fate. It predicts that the universe must be either expanding or contracting. Before the introduction of general relativity, space and time were thought of only as an arena in which events took place. After general relativity, physicists realized that space and time are dynamic entities that can be affected by mass, forces, and energy.

relatively weak gravity

intense gravity close to star

moderately deep gravitational well

WHITE DWARF STAR

A white dwarf is a very dense, planetsized star that can be thought of as producing a smaller but deeper dent in space-time than does a star like the Sun.

warped space-time

PINCHED SPACE

Instead of a two-dimensional sheet, four-dimensional space-time can also be visualized as a threedimensional volume that is narrowed or “pinched in” around large masses.

intense gravity

relatively weak gravity

deep, steep gravitational well

relatively weak gravity

massive, dense neutron star

NEUTRON STAR

A neutron star is an exceedingly dense stellar remnant that makes a very deep dent in space-time. A neutron star significantly deflects light passing by, but cannot capture it. BLACK HOLE

distortion of space-time caused by the Sun’s mass deflects light from distant galaxy space-time around the Sun is warped by the Sun’s mass, creating a so-called a “gravitational well”

In a black hole, all the mass is concentrated into an infinitely dense point at the center, called a singularity. A singularity produces an infinite distortion in space-time—a bottomless gravitational well. Any light that passes a boundary called the “event horizon” near the entrance to this well cannot return.

event horizon, beyond which nothing, not even light, can break free of the gravitational field extremely intense gravity gravitational well of infinite depth, with steepness (gravity) increasing to infinity singularity at the center of the black hole

QUANTUM GRAVITY telescope on Earth Sun

Although general relativity accurately describes the universe on a large scale, it has little to say about the subatomic world in which many scientists believe gravity must originate. This subatomic world is modeled by another great theory of physics, called quantum mechanics, which itself has little to say about gravity. There is, it seems, little in common between the smooth, predictable interactions of space-time and matter predicted by general relativity and the jumpy subatomic world modeled by quantum MULTIDIMENSIONAL SPACE-TIME mechanics, in which changes in energy and matter These figures, called Calabi–Yau occur in quanta (discrete steps, see p.28). A key goal spaces, are purported to hold six or of modern physics is to find a unifying theory—a more dimensions “curled up” within “quantum theory of gravity” or “theory of everything”— them. By incorporating one of these tiny objects at each point in spacethat unites relativity and quantum mechanics, and time, string theorists envisage ten harmonizes gravity with the other fundamental forces of or more dimensions. nature. One of the best hopes lies in string theory (see p.31). Most early-21st-century theories of everything suppose that the universe has more dimensions than the easily observed three of space and one of time. The effect of gravity on the path of light is not obvious unless an observer looks deep into space at the universe’s most massive objects—clusters of galaxies. This image shows galaxies as white blobs. Their combined gravity bends light so much that the images of more distant galaxies appear as blue streaks, stretched and squashed by the galaxy cluster’s gravity.

Calabi–Yau space

I N TR OD U CT I ON

GRAVITY BENDING LIGHT

44

WHAT IS THE UNIVERSE?

EXPANDING SPACE 22–23 The scale of the universe 34–37 Radiation The Big Bang 48–51 The fate of the universe 58–59 Galaxy clusters 326–27

the universe 6 billion years ago was much smaller galaxies close together

A CRUCIAL PROPERTY

of the universe is that it is expanding. It must be growing, because distant galaxies are quickly receding from Earth and more distant ones are receding even faster. Assuming that the universe has always been expanding, it must once have been smaller and denser—a fact that strongly supports the Big Bang theory of its origin.

free gas and dust not yet absorbed into galaxies

MEASURING EXPANSION 15 billion years ago, size of universe is zero—a possible Big Bang occurs universe expanding at a constant rate in the past

12 billion years ago, size of universe is zero universe expanding at a faster rate then slowing down

NY EARS AGO

AGE OF THE UNIVERSE

distance from Earth (measured by variable stars)

HUBBLE CONSTANT

The recession velocity of remote galaxies rises with distance, and this relationship forms a straight line on a graph. Estimates of the line’s slope yield values of the Hubble constant.

Cosmologists can estimate present day the age of the universe by extrapolating its expansion rate backward to the point at which the size of the observable universe was zero. Depending on how the expansion rate has changed, estimates for the universe’s age range from 12 to 15 billion years. The current best estimate is 13.7 billion years.

THE NATURE OF EXPANSION

INTRODUCTION

BI LL IO

3

recessional velocity (measured by red shift)

6

BI EA LLION RS AGO

cones represent two possible histories of the expanding universe

Y

The rate of the universe’s expansion can be calculated by comparing the distances to remote galaxies and the speeds at which they are receding. The galaxies’ velocities are measured by examining the red shifts in their light spectra (see p.35). Their distances are calculated by detecting a class of stars called Cepheid variables in the galaxies and measuring the stars’ cycles of magnitude variation (see pp.282, 313). The result is a number known as the Hubble constant—an expression of the universe’s expansion rate. The value of the constant has been debated by cosmologists, but is currently thought to be about 50,000 mph (80,000 km/h) per million light-years. This means, for example, that two galaxies situated 1 billion light-years apart are receding from each other at 50 million mph (80 million km/h). On a familiar time scale, this is actually a very gradual expansion—an increase in the galaxies’ distance of 1 percent takes tens of millions of years.

Several notable features have been established about the universe’s expansion. First, although all distant galaxies are moving away, neither Earth nor any other point in space is at the center of the universe. Rather, everything is receding from everything else, and there is no center. Second, at a local scale, gravity dominates over cosmological expansion and holds matter together. The scale at which this happens is surprisingly large—even entire clusters of galaxies resist expansion and hold together. Third, it is incorrect to think of galaxies and galaxy clusters moving away from each other “through” space. A more accurate picture is that of space itself expanding and carrying objects with it. Finally, the expansion rate almost certainly varies. Cosmologists are greatly interested in establishing how the expansion rate GRAVITY may change in the future. The future rate LOCAL The galaxies above are not moving apart. They will of expansion will decide the eventual continue to collide despite cosmological expansion. fate of the universe (see pp.58–59). Galaxy clusters are also held together by gravity.

some galaxies evolve into spiral shapes PRE SENT DAY

galaxies becoming less crowded

galaxy cluster, bound by gravity, does not expand

3 BIL LION Y EARS IN TH E FUT URE

EXPANDING SPACE

TIME AND EXPANDING SPACE PEERING INTO DEEP SPACE

This Hubble “deep-field” photograph shows a jumble of galaxies viewed at different distances. Each appears as it existed billions of years ago.

diffuse, young galaxy not yet condensed into a tight spiral

young, blue galaxy 4 billion lightyears away, pictured as it was 4 billion years ago elliptical galaxy, 6 billion light-years away

spiral galaxy, 3 billion lightyears distant

The continued expansion of space, combined with the constant speed of light, turns the universe into a giant time machine. The light from a remote galaxy has taken billions of years to reach Earth, so astronomers see the galaxy as it was billions of years ago. In effect, the deeper astronomers look into space, the farther they peer into the universe’s history. In the remotest regions, they see only incompletely formed galaxies as they looked soon after the Big Bang. The most dim and distant of these galaxies is receding from Earth at speeds approaching the speed of light. Should astronomers observe such objects for millions of years, they would see them evolving more slowly than if they were closer and not being carried away so fast. At greater distances yet, beyond the observable universe (see p.23), there may exist other objects that have moved away so fast that light from them has never reached Earth.

45

EDWIN HUBBLE The American astronomer Edwin Hubble (1889–1953) is famous for being the first to prove that the universe is expanding. He showed the direct relationship between the recession speeds of remote galaxies and their distances from Earth, now known as Hubble’s Law. Hubble is also noted for his earlier proof that galaxies are external to the Milky Way and for his system of galaxy classification. The Hubble Space Telescope and the Hubble constant are both named after him.

LOOKBACK DISTANCE The expansion of space complicates the expression of distances to very remote objects, particularly those that we now observe as they existed more than 5 billion years ago. When astronomers describe the distance to such faraway objects, by convention they use the “lookback” or “light-travel-time” distance. This is the distance that light from the object has travelled through space to reach us today, and it tells us how long ago the light left the object. But because space has expanded in the interim, the distance of the galaxy when the light began its journey towards Earth is less than the lookback distance. Conversely, the true distance to the remote object (called the “comoving” DIVERGING WORLDS distance) is greater than the lookback An object described as being distance. These distinctions need to be 11 billion light-years away remembered when, for example, a galaxy (lookback distance) has a is stated as being 10 billion light-years away. greater true distance (comoving photon leaves galaxy X 1. Eleven billion years ago, a photon of light departs distant galaxy X traveling toward the Milky Way. The two galaxies are separated by 4 billion light-years of space.

5 BILLION YEARS AGO

ACCELERATING EXPANSION

This is a conceptual interpretation of how a region of space may have changed over a 9-billion-year period. As space has expanded, so the galaxies within it have been carried apart, evolving as they go. This interpretation shows expansion speeding up—a scenario gaining support from cosmologists.

Milky Way

distant galaxy X receding

2. Six billion years later, the photon has not yet reached its destination, because space has expanded, carrying the galaxies much farther apart.

3. The photon reaches the Milky Way, where an observer sees X as it was 11 billion years ago, 11 billion lightyears away (lookback distance). Meanwhile, X’s true (comoving) distance has increased to 18 billion light-years.

PRESENT DAY

photon arrives

photon travels toward Milky Way

lookback distance

galaxy X still receding

true, comoving distance

I N TR OD U CT I ON

voids between galaxy clusters progressively enlarge and become almost empty of dust and gas

11 BILLION YEARS AGO

distance), due to the effects of the universe’s expansion.

I N TRO D UC TI O N

46

“Some say the world will end in fire, Some say in ice.” Robert Frost

THE STORY OF THE UNIVERSE can be traced back to its very first instants, according to the Big Bang theory of its origins. In the Big Bang model, the universe was once infinitely small, dense, and hot. The Big Bang began a process of expansion and cooling that continues today. It was not an explosion of matter into space, but an expansion of space itself, and in the beginning, it brought time and space into existence. The Big Bang model does not explain all features of the universe, however, and it continues to be refined. Nonetheless, scientists use it as a framework for mapping the continuing evolution of the universe, through events such as the decoupling of matter and radiation (when the first atoms were formed and the universe became transparent) and the condensation of the first galaxies and the first stars. Study of the Big Bang and the balance between the universe’s gravity and a force called dark energy can even help predict how the universe will end. CRADLE OF STAR BIRTH

This pillar of gas and dust is the Cone Nebula, one of the most active cradles of star formation in the Milky Way. The clouds of material giving birth to these stars were once parts of stars themselves. The recycling of material in the life cycles of stars has been key to the universe’s enrichment and evolution.

THE BEGINNING AND END OF THE UNIVERSE

48

THE BEGINNING AND END OF THE UNIVERSE

THE BIG BANG

THE FIRST MICROSECOND

TIME, SPACE, ENERGY, AND MATTER

are all thought to have come into existence 13.7 billion years ago, in the event called the Big 34–37 Radiation Bang. In its first moments, the universe was infinitely dense, 44–45 Expanding space unimaginably hot, and contained pure energy. But within a tiny The fate of the universe 58–59 fraction of a second, vast numbers of fundamental Mapping deep space 339 particles had appeared, created out of energy as the universe cooled. Within a few hundred thousand years, these particles had combined to form the first atoms. 28–31 Matter

The timeline on this page and the next shows some events during the first microsecond (1 millionth of a second or 10–6 seconds) after the Big Bang. Over this period, the universe’s temperature dropped from about 1034°C (ten billion trillion trillion degrees) to a mere 1013°C (ten trillion degrees). The timeline refers to the diameter of the observable universe: this is the approximate historical diameter of the part of the universe we can currently observe.

IN THE BEGINNING The Big Bang was not an explosion in space, but an expansion of space, which happened everywhere. Physicists do not know what happened in the first instant after the THE PLANCK ERA Big Bang, known as the Planck era, but at No current theory of the end of this period, they believe that physics can describe gravity split from the other forces of nature, what happened in followed by the strong nuclear force (see the universe during this time. p.30). Many believe this event triggered “inflation”—a short but rapid expansion. If DIAMETER inflation did occur, it helps to explain why TEMPERATURE the universe seems so smooth and flat. During inflation, a fantastic amount of mass-energy came into existence, in tandem with an equal but negative amount of gravitational energy. By the end of singularity TIME inflation, matter had at the start of time begun to appear.

3x10–26 ft/10–26 m

1022K (18 billion trillion °F/10

THE INFLATION ERA

THE QUARK ERA

Part of the universe expanded from billions of times smaller than a proton to something between the size of a marble and a football field.

Sometimes called the electroweak era, this period saw vast numbers of quark and antiquark pairs forming from energy and then annihilating back to energy. Gluons and other more exotic particles also appeared.

A hundred-billionth of a yoctosecond 10 –35 seconds

1 yoctosecond 10 –24 seconds

A hundred-millionth of a yoctosecond 10 –32 seconds

A ten-trillionth of a yoctosecond 10 –43 seconds

THE GRAND UNIFIED THEORY ERA

105 m (62 miles/100 km)

33 ft/10 m

1027K (1,800 trillion trillion °F (1,000 trillion trillion °C)

quark

quark

quark

antiquark quark– antiquark pair

During this era, matter and energy were completely interchangeable. Three of the fundamental forces of nature were still unified.

X-boson

Grand Unified Force

electroweak force

weak nuclear force

su p

erf orc e

strong nuclear force

electromagnetic force

gravitational force

10–43 SECONDS

–12 10–36 SECONDS 10 SECONDS

gluon

SEPARATION OF FORCES

PARTICLE SOUP

Physicists believe that at the exceedingly high temperatures present just after the Big Bang, the four fundamental forces were unified. Then, as the universe cooled, the forces separated, or “froze out,” at the time intervals shown here.

I N TRO D UC TI O N

INFLATION

In a Big Bang without inflation, what are now widely spaced regions of the universe could never have become so similar in density and temperature. Inflation theory proposes that our observable universe is derived from a tiny homogeneous patch of the original universe. The effect of inflation is like expanding a wrinkled sphere—after the WRINKLED expansion, its surface appears smooth and flat.

SMOOTHER

VERY SMOOTH

EXTREMELY SMOOTH AND FLAT

About 10 –32 seconds after the Big Bang, the universe is thought to have been a “soup” of fundamental particles and antiparticles. These were continually formed from energy as particle–antiparticle pairs, which then met and were annihilated back to energy. Among these particles were some that still exist today as constituents of matter or as force carrier particles. These include quarks and their antiparticles (antiquarks), and bosons such as gluons (see pp.30–31). Other particles may have been present that no longer exist or are hard to detect—perhaps some gravitons (hypothetical gravity-carrying particles) and Higgs bosons, also hypothetical, which impart mass to other particles.

THE BIG BANG

49

EXPLORING SPACE

RECREATING THE EARLY UNIVERSE At the European Centre for Nuclear Research, also known as CERN, particle physicists are unraveling the finer details of the early universe by smashing particles together in particle accelerators and searching for traces of other fundamental particles. In doing so, they explore the constituents of matter and the forces that control their interactions. CERN scientists have even recreated conditions like those shortly after the Big Bang, by creating plasmas containing free quarks and gluons. ULTRA-HIGH-ENERGY PROTON COLLISION

In this image obtained by a detector at the Large Hadron Collider at CERN, the yellow lines show the paths of particles produced from the collision of ultra-high-energy protons.

106m (620 miles/1,000 km) billion trillion °C) 1021K (1.8 billion trillion °F/1 billion trillion °C)

109m (620,000 miles/1 million km)

1012m (620 million miles/1 billion km)

1018K (1.8 million trillion °F/1 million trillion °C)

1015K (1,800 trillion °F/1,000 trillion °C)

SEPARATION OF THE ELECTROWEAK FORCE

Near the end of the quark era, the electroweak force separated into the electromagnetic force and the weak interaction (see p.30). From then on, the forces of nature and physical laws were as they are now experienced. 1 zeptosecond 10 –21 seconds

1 attosecond 10 –18 seconds

1 femtosecond 10 –15 seconds

1 picosecond 10 –12 seconds

1 nanosecond 10 –9 seconds

1 microsecond 10 –6 seconds

FREEZE OUT AND ANNIHILATION Higgs boson (hypothetical)

Particle–antiparticle pairs, including quarks– antiquarks, were still constantly forming and returning to energy. For each type of particle, the temperature would eventually drop to the point where the particles “froze out”—they could no longer form from the background pool of energy. Most free particles and antiparticles of each type were rapidly annihilated, leaving a small residue of particles. As quarks and antiquarks froze out at the end of the quark era, instead of being annihilated, some began grouping to form heavier particles.

photon

antineutrino

quark–antiquark forming and annihilating

QUARKS BECOMING BOUND INTO HEAVIER PARTICLES BY GLUONS

Higgs boson (hypothetical) graviton (hypothetical)

W-boson

MORE MATTER THAN ANTIMATTER X-boson (hypothetical) antiquark

One of the particles thought to have existed during the early moments of the Big Bang was a very-high-mass particle, the X-boson (along with its own antiparticle, the anti-Xboson). The X-boson and its antiparticle were unstable and decayed into other particles and antiparticles—quarks, antiquarks, electrons, and positrons (antielectrons). A peculiarity of the X-boson and its antiparticle is that, when they decayed, they produced a tiny preponderance of particles over antiparticles— that is, about a billion and one particles to each billion antiparticles. When these were later annihilated, a residue of particles remained, and it is postulated that these gave rise to all the matter currently in the universe.

decaying X-boson

quark–antiquark pair

X-boson decay products (particles and antiparticles)

quark

antiquark

particles and antiparticles meet, converting their combined matter into pure energy (photons)

slight excess of particles left over

quark and antiquark forming from energy, and immediately returning to energy as they meet

50

THE BEGINNING AND END OF THE UNIVERSE

THE EMERGENCE OF MATTER

GEORGE GAMOW

About 1 microsecond (10 -6 or one millionth of a second) after the Big Bang, the young universe contained, in addition to vast quantities of radiant energy, or photons, a seething “soup” of quarks, antiquarks, and gluons. Also present were the class of fundamental particles called leptons (mainly electrons, neutrinos, and their antiparticles) forming from energy and then being annihilated back to energy. The stage was set for the next processes of matter formation that led to our current universe. First, quarks and gluons met to make heavier particles—particularly protons and a smaller number of neutrons. Next, the neutrons combined with some of the protons to form atomic nuclei, THE NEXT HALF-MILLION YEARS mainly those of helium. The remaining protons, The timeline on these two pages shows events from 1 microsecond to 500,000 years after the destined to form the nuclei of hydrogen atoms, Big Bang. The temperature dropped from stayed uncombined. Finally, after half a million 1013K (18 trillion °F/10 trillion °C) to 4,500°F years, the universe cooled sufficiently for (2,500°C). Today’s observable universe electrons to combine with the free protons and expanded from about 50 light-hours (100 billion km) to many millions of light-years wide. helium nuclei—so forming the first atoms.

DIAMETER TEMPERATURE

TIME

electron

Influenced by the original “Big Bang” concept of Georges Lemaître, Ukrainian American physicist George Gamow (1904–1968) played a major role in developing the “hot Big Bang” theory. This, supplemented by inflation, is the mainstream theory today. With his students Alpher and Herman, Gamow studied details of the theory, estimating the present cosmic temperature as 5K above absolute zero.

60 billion miles/100 billion km

600 billion miles/1,000 billion km

1013K (18 trillion °F/10 trillion °C)

1012K (1,800 billion °F/1,000 billion °C)

1010K (18 billion °F/10 billion °C)

HADRON ERA

LEPTON ERA

NUCLEOSYNTHESIS ERA

Around the beginning of this era, quarks and antiquarks began combining to form particles called hadrons. These included baryons (protons and neutrons), antibaryons, and mesons.

During this era, leptons (electrons, neutrinos, and their antiparticles) were very numerous. By its end, the electrons annihilated with positrons (antielectrons).

Neutrons gradually converted into protons as the universe cooled, but when there was about one neutron for every seven protons, most remaining neutrons combined with protons to make helium nuclei, each with two protons and two neutrons.

1 microsecond 10 –6 seconds—1 millionth of a second

1 millisecond 10 –3 seconds—1 thousandth of a second

1 second

pion, a type of meson

newly formed hadron

photon

10 light-years (1 light-year = 5.88 trillion miles/9.46 trillion km)

positron (antielectron)

electron

electron

proton

THE FIRST PROTONS AND NEUTRONS

positron

After 1 microsecond, the universe had cooled enough for quarks and antiquarks to combine in twos and threes to form heavier particles, in a process called quark confinement. “Up” quarks and “down” quarks combined with gluons to make protons and neutrons. Other hadrons, such as mesons and antibaryons, also formed, but either quickly decayed or were annihilated. For the next second, the residue of protons and neutrons could turn into each other, emitting and absorbing electrons and neutrinos as they did so.

neutron

antineutrino

photon

neutrino

helium-3 nucleus

free quark

THE FIRST NUCLEI deuterium nucleus

pion

gluon

proton, formed from quarks and gluons

free quark neutron, formed from quarks and gluons

helium-4 nucleus

100 seconds after the Big Bang, collisions between protons and neutrons began forming helium-4 nuclei (containing 2 protons and 2 neutrons) as well as tiny amounts of other atomic nuclei, such as helium-3 (2 protons and 1 neutron), lithium (3 protons and 4 neutrons), and deuterium (1 proton and 1 neutron). Termed Big Bang nucleosynthesis, these reactions finished within two to three minutes. By that time, the nuclei of 98 percent of today's helium atoms had formed. The reactions also mopped up all the free neutrons.

THE BIG BANG

51

EVIDENCE FOR THE BIG BANG The strongest evidence for the Big Bang is the radiation it left, called the cosmic microwave background radiation (CMBR). George Gamow (see panel, opposite) predicted the radiation’s existence in 1948. Its detection in the 1960s was confirmation, for most cosmologists, of the Big Bang theory. Other observations help support the theory. BACKGROUND RADIATION The spectrum of the CMBR, discovered by Arno Penzias and Robert Wilson (below), indicates a uniformly hot early universe.

EXPANSION If the universe is expanding and cooling, it must once have been much smaller and hotter. BALANCE OF ELEMENTS Big Bang theory exactly predicts the proportion of light elements (hydrogen, helium, and lithium) seen in the universe today. GENERAL RELATIVITY Einstein's theory predicts that the universe must either be expanding or contracting—it cannot stay the same size.

DARK NIGHT SKY If the universe were both infinitely large and old, Earth would receive light from every part of the night sky and it would look bright—much brighter even than the densest star field (above). The fact that it is not is called Olbers' paradox. The Big Bang resolves the paradox by proposing that the universe has not always existed.

10,000 light-years

100 million light-years

108K (180 million °F/100 million °C)

3,000K (4,900°F/2,700°C)

OPAQUE ERA

BALANCE OF ELEMENTS

MATTER ERA

During this relatively lengthy era, the ocean of matter particles (comprising mainly electrons, protons, and helium nuclei) were in a continual state of interaction with photons (radiant energy), making the universe “foggy”.

At the end of the Opaque Era, many more free protons existed than helium nuclei, or other atomic nuclei. The scene was set for the first atoms to form. When they did, about nine hydrogen atoms were made for each helium atom. A few lithium and deuterium (heavy hydrogen) atoms also formed.

At the start of our present era, photons were free to travel through the universe. Most electrons were bound to atoms until the first stars formed, reheating matter.

200 seconds

300,000 years

electron

OPAQUE UNIVERSE

photon

For hundreds of thousands of years, the universe continued to expand and cool, but it was still too energetic for atoms to form. If electrons momentarily met with protons or helium nuclei, they were quickly split apart by photons, which were themselves trapped in a process of continual collision with the free electrons. This scattering of photons by electrons meant that the photons could travel hardly any distance in a straight line. If an observer could have seen it at the time, the universe would have resembled a dense fog.

proton electron

helium-3 nucleus free photon

THE FIRST ATOMS

helium-4 nucleus hydrogen atom—nine times more numerous than any other atoms

Some 300,000 years after the Big Bang, when the temperature had dropped to about 4,900°F/ 2,700°C), protons and atomic nuclei began to capture electrons, forming the first atoms. Electrons were now bound up in atoms, so they no longer scattered photons. Matter and radiation therefore became “decoupled,” and the photons were released to travel through the universe as radiation—the universe became transparent. These first free photons are still detectable as the cosmic microwave background radiation (CMBR).

I N TRO D UC TI ON

hydrogen atom (single proton and single electron)

helium atom (two protons, two neutrons, and two electrons)

STUDYING THE BIG BANG

Scientists at CERN (see p.49) are attempting to simulate the incredibly hot and dense conditions that followed the Big Bang using a device called the Large Hadron Collider (LHC). In a tunnel that is 17 miles (27 km) long, beams of particles are smashed together at high speeds and the products studied. Shown here is one of the detectors, called the Compact Muon Solenoid (CMS).

54

THE BEGINNING AND END OF THE UNIVERSE

OUT OF THE DARKNESS THE PERIOD FROM THE BIRTH

28–31 Matter 34–37 Radiation Stars 232–33 Stellar end points 266–67 Galaxy evolution 306–309 Galaxy superclusters 336–39

of atoms, 300,000 years after the Big Bang, to the ignition of the first stars, hundreds of millions of years later, is known as the “dark ages” of the universe. What happened in this era, and the subsequent “cosmic renaissance” as starlight filled the universe, is an intricate puzzle. Astronomers are solving it by analyzing the relic radiation of the Big Bang and using the world’s most powerful telescopes to peer to the edges of the universe.

THE AFTERMATH OF THE BIG BANG At an age of 350,000 years, the universe was full of photons of radiation streaming in all directions, and of atoms of hydrogen and helium, neutrinos, and other dark matter. Although it was still hot, at 4,900°F (2,500°C), and full of radiation, astronomers see no light if they try to peer back to that moment. The reason is that as the universe has expanded, it has stretched the wavelengths of radiation by a factor of a thousand. The photons reach Earth not as visible light, but as low-energy photons of cosmic microwave background radiation (CMBR). INFANT UNIVERSE Their wavelength, once characteristic of the This WMAP image (see p.36), is an all-sky picture of fireball of the universe, is now that of a cold the minute fluctuations in the temperature of the object with a temperature of -454°F (-270°C) CMBR, which relate to early irregularities in matter —only 5°F (3°C) above absolute zero. density. In effect, it is an image of the infant universe.

THE DARK AGES Earth will never receive visible light from the period before the first stars ignited, a few hundred million years after the Big Bang, but cosmologists can reconstruct what happened during that time using other data, such as those of the CMBR. The CMBR reveals tiny fluctuations in the density of matter at the time the first atoms formed. Cosmologists think that gravity, working on these ripples, caused the matter to begin forming into clumps and strands. These irregularities in the initial cloud of matter probably laid the framework of present-day large-scale objects, such as galaxy superclusters (see pp.336–37). The development of such structures over billions of years has been simulated with computers. These simulations rely on assumptions about the density and properties of matter, including dark matter, in the infant universe, as well as the influence of dark energy (a force opposing gravity, see p.58). Some simulations closely resemble the distribution of matter seen in the universe today.

I N TRO D UC TI O N

faint irregularity

matter filament

denser filament of matter containing galaxy clusters

knot of matter has become a galaxy supercluster

UNIVERSE AT 500,000 YEARS OLD

1.3 BILLION YEARS OLD

5 BILLION YEARS OLD

13.7 BILLION YEARS OLD

This computer simulation of the development of structure in the universe starts with matter almost uniformly dispersed in a cube that is 140 million light-years high, wide, and deep.

A billion years later, considerable clumping and filament formation has occurred. To compensate for the cosmic expansion since the previous stage, the cube has been scaled to size.

A further 4 billion years later, and (again, after rescaling) the matter has condensed into some intricate filamentous structures interspersed with sizable bubbles or voids of empty space.

The matter distribution in the simulation now resembles the kind of galaxy-supercluster structure seen in the local universe (within a few billion light-years).

OUT OF THE DARKNESS

55

EARLY GALAXIES Astronomers are still trying to pinpoint when the very first stars ignited and in what types of early galactic structures this may have occurred. Recent infrared studies, with instruments such as the Spitzer Space Telescope and Very Large Telescope, have revealed what seem to be very faint galaxies, with extremely high red shifts, existing as little as 500 million years after the Big Bang. Their existence indicates that well-developed precursor knots and clumps of condensing matter may have existed as little as 100 to 300 million years after the Big Bang. It is within these structures that the first stars probably formed.

EARLY GALAXY IN INFRARED

The purple glow in this image is an active galactic nucleus. It is seen as it was only 700 million years after the Big Bang.

THE FIRST STARS The first stars, which may have formed only 200 million years after the Big Bang, were made almost entirely of hydrogen and helium—virtually no other elements were present. Physicists think that star-forming nebulae that lacked heavy elements condensed into larger gas clumps than those of today. Stars forming from these clumps would have been very large and hot, with perhaps 100 to 1,000 times the mass of the Sun. Many would have lasted only a few million years before dying as supernovae. Ultraviolet light from these stars may have triggered a key moment in the universe’s evolution—the reionization of its hydrogen, turning it from a neutral gas back into the ionized (electrically charged) form seen today. Alternatively, radiation from quasars (see p.320) may have reionized the universe. DEATH OF MEGASTARS

The first, massive stars may have exploded as “hypernovae”— events associated today with black-hole formation and violent bursts of gamma rays. These artist’s impressions depict one model of hypernova development.

gammaray jet

200-solar-mass “megastar”

IONIZING POWER OF STARS

These young, high-mass stars in the Orion Nebula ionize the gas around them, causing it to glow. Ionized hydrogen between galaxy clusters today may have been created by the far fiercer radiation of the first generation of stars and hypernovae.

core collapses into star’s own black hole star sheds outer shells of matter

COSMIC CHEMICAL ENRICHMENT

BEFORE STARS (300,000 YEARS AFTER THE BIG BANG)

COMPOSITION OF THE UNIVERSE

The early universe consisted of hydrogen and helium, with a trace of lithium. Today it still consists mainly of hydrogen and helium, but stellar processes have boosted the contribution from other chemical elements to more than 2 percent.

hydrogen 76%

helium 24%

AFTER MANY CYCLES OF STAR BIRTH AND DEATH

hydrogen 74%

helium 23%

trace of lithium oxygen 1% carbon 0.5% neon 0.5% iron 0.1% nitrogen 0.1% + traces of other elements

STARDUST

Supernova remnant Cassiopeia A is a sphere of enriched material expanding into space. Elements heavier than iron have mostly been made and dispersed by supernovae.

I N TR OD U CT I ON

During the course of their lives and deaths, the first massive stars created and dispersed new chemical elements into space and into other collapsing protogalactic clumps. A zoo of new elements, such as carbon, oxygen, silicon, and iron, was formed from nuclear fusion in the hot cores of these stars. Elements heavier than iron, such as barium and lead, were formed during their violent deaths. Second- and third-generation stars, smaller than the primordial megastars, later formed from the enriching interstellar medium. These stars created more of the heavier elements and returned them to the interstellar medium via stellar winds and supernova explosions. Galactic mergers and the stripping of gas from galaxies (see p.327) led to further intergalactic mixing and dispersion. These processes of recycling and enrichment of the cosmos continue today. In the Milky Way galaxy, the new heavier elements have been essential to the formation of objects from rocky planets to living organisms.

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THE BEGINNING AND END OF THE UNIVERSE

LIFE IN THE UNIVERSE 29 Chemical compounds

THE ONLY KNOWN LIFE IN THE COSMOS

is that on Earth. Life on Earth is so ubiquitous, however, and the universe Detecting extra-solar planets 297 so enormous, that many scientists Looking for Earths 299 think there is a very good chance that life also exists elsewhere. Much depends on whether the development of life on Earth was a colossal fluke—the product of an extremely improbable series of events—or, as many believe, not so unexpected given what is suspected about primordial conditions on the planet. Life on Earth 127

LIVING ORGANISMS What exactly constitutes a living organism? Human ideas on this are heavily reliant on the study of life on Earth, since scientists have no experience of the potential breadth of life beyond. Nonetheless, biologists are agreed on a few basic features that distinguish life from non-life anywhere in the cosmos—as a bare minimum, a living entity must be able to replicate itself and, over time, to evolve. Beyond that, the definition of life is not universally agreed. As an illustration, there is uncertainty about whether viruses are living. Although they self-replicate, viruses lack some characteristics that most biologists consider essential to life; notably, they do not exist as cells or possess their own biochemical machinery. It is VIRUS PARTICLES also uncertain that other characteristics Viruses, such as this hepatitis virus, are on the border common to life on Earth, such as carbon between living and non-living chemistry or the use of liquid water, must matter. They self-replicate but inevitably be a feature of extraterrestrial can do so only by hijacking the life. Disagreements over such matters metabolic machinery of animal, plant, or bacterial cells. add complexity to discussions of the likelihood of life beyond Earth.

INTRODUCTION

ORIGINS OF LIFE Most scientists agree that the beginnings of life on Earth were linked to the accumulation of simple organic (carbon-containing) molecules in a “primordial soup” in Earth’s oceans not long after their formation. The molecules originated from reactions of chemicals in Earth’s atmosphere, stimulated by energy, perhaps SUBZERO LIFE FORM from lightning. Within the soup, over This so-far-unclassified life millions of years the organic compounds form was found living deep in reacted to form larger and more complex the Antarctic ice sheet. Life can exist in a wider range of molecules, until a molecule appeared with conditions than once thought. the capacity to replicate itself. By its nature, this molecule—a rudimentary gene— became more common. Through mutations and the mechanism of natural selection, variants of this gene developed more sophisticated survival adaptations, eventually evolving into a bacteria-like cell—the precursor of all other life on Earth. Many evolutionary STROMATOLITES biologists would say Some of the earliest that the decisive remains of life are fossil event was the stromatolites—mineral mounds built billions of appearance of the years ago in shallow self-replicator, seas by cyanobacteria after which living (blue-green algae). Stromatolites still grow on organisms would the Australian coast (left). inevitably follow.

EXPLORING SPACE

RECREATING PRIMORDIAL EARTH In 1953, American chemist Stanley Miller (1930–2007) recreated what he thought was Earth’s primordial atmosphere in a flask. He sent sparks, simulating lightning, into the gas mixture, which lacked oxygen. The result was many different amino acids—some of the basic building blocks of life.

STANLEY MILLER

Here, Stanley Miller recreates the experiment he first conducted as a graduate student. It showed that amino acids could have formed in Earth’s oxygen-free early atmosphere.

LIFE IN THE UNIVERSE

HOW RARE IS LIFE? Until about 30 years ago, the ranges of conditions thought essential to life, such as those of temperature and humidity, were thought to be narrow. Since then, scientists have found extremophiles (organisms that thrive in extreme conditions) living in adverse environments on Earth. Organisms may live deep in ice sheets or in boiling-hot water around vents in the ocean floor. Some exist in communities divorced from sunlight and live on energy from chemical sources. Bacteria are even found living 2 miles (3 km) deep in the Earth’s crust, living on hydrogen, which they convert to water. Extremophiles have encouraged the idea that life can exist in a wide range of conditions. Some scientists are still hopeful that extraterrestrial life will be found in the solar system, although exploration of the most likely location, Mars, has proved negative so far. Beyond the solar system, many scientists think that life must be widespread. At these remote distances, scientists are most interested in whether intelligent, contactable life exists. In the 1960s, American radio astronomer Frank Drake (b. 1930) developed an equation for predicting the number of civilizations in the galaxy capable of interstellar communication. Because few of the factors in the equation can be estimated accurately, applying it (see panel, right) can have any outcome from less than one to millions, depending on the estimated values. Nevertheless, it is not unreasonable to suggest that at least a few such civilizations may exist in the Milky Way.

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ALIEN CIVILIZATIONS? Applying the Drake Equation involves estimating factors, such as the fraction of stars that develop planets, then multiplying all the factors. The example below uses only moderately optimistic estimates (some are just guesses). RATE OF STAR BIRTH A fair estimate would

be 50 new stars per year in the Milky Way. 50% of new stars develop planets

STARS WITH PLANETS Perhaps 50 percent

of these stars develop planetary systems. 0.4 planets will be habitable

HABITABLE PLANETS On average, maybe

only 0.4 planets per system are habitable. 90% of habitable planets develop life

PLANETS WITH LIFE Life may well develop on 90% of habitable planets. 90% of life-bearing planets bear only simple life

10%

INTELLIGENT LIFE Possibly about 10% of new instances of life develop intelligence.

90% of intelligent life never talks to the stars

10%

COMMUNICATING LIFE Possibly only 10% of

such life develops interstellar communications. some civilizations die before contact

LIFE SPAN OF CIVILIZATION These civilizations

might, on average, last 10,000 years. 900 civilizations alive today

LIFE ON EUROPA?

Jupiter’s moon Europa is covered with ice. There may be a liquid ocean underneath, possibly containing water, with the possibility of life. RECOGNIZING LIFE

If humans ever encounter extraterrestrial life, it is by no means certain that we would immediately recognize it. Not everyone would see life, rather than just discoloration, in this algal bloom growing in the North Atlantic.

CONCLUSION

Using the estimates above, one might expect there to be about 50 x 0.5 x 0.4 x 0.9 x 0.1 x 0.1 x 10,000 = 900 alien civilizations in our galaxy that, in theory, we should be able to communicate with. However, some of the estimates may be wildly wrong.

LOOKING FOR LIFE

MESSAGE TO ALIENS

The Arecibo Telescope message contains symbols of a human body, DNA, the solar system, and the Arecibo dish itself.

INTRODUCTION

Attempts to identify extraterrestrial life forms follow a number of approaches. Within the solar system, scientists analyze images of planets and moons for signs of life and send probes to feasible locations, such as Mars and Saturn’s moon Titan. Outside the solar system, the main focus of the search is SETI (the search for extraterrestrial intelligence)—a set of programs that involve scanning the sky for radio signals that look like they were sent by aliens. A search has also begun for Earth-like planets around nearby stars (see pp.296–99). Finally, CETI (communication with extraterrestrial intelligence) involves broadcasting the presence of humans by sending signals toward target stars. In 1974, a CETI message in binary code was sent toward the M13 star cluster, 21,000 light-years away. In 1999, the more elaborate “Encounter 2001” message was sent from a Ukrainian radio telescope toward ARECIBO DISH The Arecibo Telescope in some nearby Sun-like Puerto Rico is the world’s stars. Even if aliens pick largest single-dish radio up this message, we can telescope. It has been expect no reply for at used extensively for SETI least a century. and in one CETI attempt.

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THE BEGINNING AND END OF THE UNIVERSE

THE FATE OF THE UNIVERSE

If the universe has a massenergy density close to or just less than the critical value, and should the effects of dark energy tail off, the universe might continue to expand at a rate that slowly decreases but never comes to a complete halt. Over unimaginably long periods of time, it suffers a lingering cold death or “Big Chill.”

ALTHOUGH IT IS POSSIBLE THAT THE UNIVERSE

will last forever, the types of structures that exist in it today, such as 24–27 Celestial objects planets, stars, and galaxies, almost certainly will not. At some 28–31 Matter distant point in the future, our galaxy and others will either 40–43 Space and time be ripped apart, suffer a long, protracted, cold death, or be 48–51 The Big Bang crushed out of existence in a reverse of the Big Bang. Which of these fates befalls the universe depends to a considerable extent on the nature of dark energy—a mysterious, gravity-opposing force recently found to be playing a major part in the universe’s large-scale behavior. 22–23 The scale of the universe

BIG CHILL

BIG CRUNCH AND BIG CHILL

FOUR POTENTIAL FATES

Until recently, cosmologists assumed that the universe’s expansion rate (see pp.44–45) must be slowing, due to the “braking” effects of gravity. They also believed that a single factor—the universe’s mass-energy density—would decide which of two basic fates awaited it. Cosmologists measure the density of both mass and energy together since Einstein demonstrated that mass and energy are equivalent and interchangeable (see p.41). They calculated that if this density was above a critical value, gravity would eventually cause the universe to stop expanding and collapse in a fiery, all-annihilating implosion (a “Big Crunch”). If, however, the universe’s density was below or exactly on the critical value, the universe would expand forever, albeit with its expansion rate gradually slowed by gravity. In this case, the universe would end in a lengthy, cold death (a “Big Chill”). Research aimed at resolving this issue found that the universe has properties suggesting that it is extremely close to being “flat” (opposite), with a density of exactly the critical value. Even though some of the mass-energy in the universe needed to render it flat seemed hard to locate, its density must be near the critical value, and so its most likely fate was eternal expansion. However, in the late 1990s, models of the fate of the universe were thrown into confusion by new findings indicating that the universe’s expansion is not slowing down at all.

Depending on the average density of the universe and the future behavior of dark energy, the universe has a number of possible different fates. Four alternatives, of differing likelihood, are depicted here.

MODIFIED BIG CHILL

If the effects of dark energy continue as they do at present, the universe will expand at an increasing rate whatever its density. Structures that are not bound by gravity will fly apart, ultimately at speeds faster than the speed of light (space itself can expand at such speed, although matter and radiation cannot). This scenario will also end in a lingering cold death or Big Chill.

INTRODUCTION

DARK ENERGY The new findings (see above) came from studies of supernovae in BIG RIP remote galaxies. The apparent brightness of these exploding stars can be If the strength of dark energy used to calculate their distance, and by comparing their distances with increased, it could overcome all the red shifts of their home galaxies, scientists can calculate how fast the the fundamental forces and universe was expanding at different times in its history. The calculations totally disintegrate the universe in a “Big Rip.” This could happen showed that the expansion of the universe is accelerating and that some 20–30 billion years from now. repulsive force is opposing gravity, causing matter to fly apart. This force First galaxies would be torn has been called dark energy, and its exact nature is apart, then solar systems. A few uncertain, though it appears similar to a gravitySUPERNOVAE CLUES months later, stars and planets Type Ia supernovae, like opposing force, the “cosmological constant,” would explode, followed shortly that depicted here, all by atoms. Time would then stop. proposed by Albert Einstein as part of his have the same intrinsic theory of general relativity (see pp.42–43). The brightness. Thus, their existence of dark energy also accounts for the DARK ENERGY DOMINANCE apparent brightness energy provides 70 percent of the massmissing mass-energy in the universe required Dark reveals their distance. energy density of the universe. Atom-based to make it flat (above), and modifies the matter (in stars and the interstellar medium) number of possible fates for the universe. and neutrinos contribute just 5 percent.

SUPERNOVA DISCOVERY

DARK ENERGY

dark energy about 70% 3 WEEKS BEFORE

AFTER SUPERNOVA

DIFFERENCE

neutrinos 0.3%, stars 0.5%, heavy elements 0.03%

dark matter about 25%

free hydrogen and helium 4%

THE FATE OF THE UNIVERSE

THE GEOMETRY OF SPACE

TIME

Cosmologists base their ideas on the fate of the universe partly on mathematical models. These indicate that, depending on its mass-energy density, the universe has three possible geometries, each with a different space-time curvature that can be represented by a 2-D shape. Before the discovery of dark energy, there was a correspondence between these geometries and the fate of the universe. A positively curved or “closed” universe was envisaged to end in a Big Crunch and a negatively curved or “open” universe in a Big Chill. A “flat” universe would also end in a Big Chill but one in which the universe’s expansion eventually slows to a virtual standstill. With the discovery of dark energy, the correspondence no longer holds. If dark energy remains constant in intensity, any type of universe may expand forever. If dark energy is capable of reversing, any type of universe could end in a Big Crunch. Currently, the most favored view is that the universe is flat and will undergo an accelerating expansion. A cataclysmic “Big Rip” scenario, in which increasing dark energy big crunch tears the universe apart, is less likely.

BIG CRUNCH

present day

BIG BANG

In this version of doomsday, all matter and energy collapse to an infinitely hot, dense singularity, in a reverse of the Big Bang. This scenario currently looks the least likely unless the effect of dark energy reverses in future. Even if it did happen, the earliest it could do so would be tens of billions of years from now.

At a very distant stage of the Big Chill, all the universe’s matter, even that in black holes, will have decayed or evaporated to radiation. Apart from some very longwavelength photons, the only constituents of photon the universe will be neutrinos, electrons, and positrons. neutrino

FLAT UNIVERSE

If the density of the universe is exactly on a critical value, it is “flat.” In a flat universe, parallel lines never meet. The 2-D analogy is a plane. The universe is thought to be flat or nearly flat. CLOSED UNIVERSE

If the universe is denser than a critical value, it is positively curved or “closed” and is finite in mass and extent. In such a universe, parallel lines converge. The 2-D analogy is a spherical surface. OPEN UNIVERSE

If the universe is less dense than a critical value, it is negatively curved or “open” and infinite. The 2-D analogy of such a universe is a saddle-shaped surface on which parallel lines diverge.

A COLD DEATH If the universe peters out in a Big Chill, its death will take a long time. Over the next 1012 (1 trillion) years, galaxies will exhaust their gas in forming new stars. About 1025 (10 trillion trillion) years in the future, most of the universe’s matter will be locked up in star corpses such as black holes and burned-out white dwarfs circling and falling into the supermassive black holes at the centers of galaxies. At 1032 (1 followed by 32 zeros) years from now, protons will start decaying to radiation (photons), electrons, positrons, and neutrinos. All matter not in black holes will fall apart. After another 1067 years, black holes will start evaporating by emitting particles and radiation, and in about 10100 years, even supermassive black holes will evaporate. The utterly cold, dark universe will be then nothing but a diffuse sea of photons and fundamental particles. FATE OF GALAXIES

A trillion years from now, the universe will contain just old, fading, galaxies. All their gas and dust will be used up and most of the stars will be dying.

INTRODUCTION

FINAL SURVIVORS

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I NT RO DU C TI ON

60

“Mortal as I am, I know that I am born for a day. But when I follow at my pleasure the serried multitude of the stars in their circular course, my feet no longer touch the Earth.” Ptolemy

OBJECTS IN THE UNIVERSE—galaxies, stars, planets, nebulae—are scattered across three dimensions of space and one of time. Viewed from widely separated locations in the universe, their relative positions look completely different. To find objects in space, study their movements, and make celestial maps, astronomers need an agreed reference frame, and for most purposes the frame used is Earth itself. The prime element of this Earth-based view is the celestial sphere—an imaginary shell around Earth to which astronomers pretend the stars are attached. Apparent movements of celestial objects on this sphere can be related to the actual movements of Earth, the planets (as they orbit the Sun), the Moon (as it orbits Earth), and the stars as they move within the Milky Way. Understanding the celestial sphere, and conventions for naming and finding objects on it, are essential first steps in astronomy. MOVEMENT ON THE SKY

This photograph, obtained over a four-hour period from the Las Campanas Observatory in Chile, looks toward the south celestial pole. The circular, clockwise star trails across the sky are a feature of the Earth-based view of the cosmos, since they result solely from the Earth’s rotation.

THE VIEW FROM EARTH

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THE VIEW FROM EARTH

THE CELESTIAL SPHERE Earth’s axis is tilted at 23.5° Earth’s axis of spin

celestial sphere

stars are fixed to the sphere’s surface and appear to move in opposite direction of Earth’s spin

THE SKY AS A SPHERE To an observer on Earth, the stars appear to move slowly across the night sky. Their motion is caused by Earth’s rotation, although it might seem that the sky is spinning around our planet. To the observer, the sky can be imagined as the inside of a sphere, known as the celestial sphere, to which the stars are fixed, and relative to which the Earth rotates. This sphere has features related to the real sphere of the Earth. It has north and south poles, which lie on its surface directly above Earth’s North and South Poles, and it has an equator (the celestial equator), which sits directly the Sun and planets above Earth’s equator. The are not fixed on the celestial sphere, but celestial sphere is like a move around on, or celestial version of a globe— close to, a circular path called the ecliptic the positions of stars and galaxies can be recorded on celestial equator—a it, just as cities on Earth circle on the celestial have their positions of latitude sphere concentric and longitude on a globe. with Earth’s equator

The celestial sphere is purely imaginary, with a specific shape but no precise size. Astronomers use exactly defined points and curves on its surface as references for describing or determining the positions of stars and other celestial objects.

line perpendicular to ecliptic plane (plane of Earth’s orbit around Sun)

FOR CENTURIES, humans

have known that stars lie at different distances from Earth’s orbit 124 Earth. However, when recording Mapping the sky 348–53 the positions of stars in the Using the sky guides 428–29 sky, it is convenient to north celestial lies pretend that they are all stuck to the inside of pole directly above North a sphere that surrounds Earth. The idea of this Earth’s Pole sphere also helps astronomers to understand how their location on Earth, the time of night, and the time of year affect what they see in the night sky. Celestial cycles 64–67

IMAGINARY GLOBE

vernal or spring equinox (first point of Aries)

Earth’s North Pole

Earth’s spin

Earth

Earth’s equator

Sun’s motion

EFFECTS OF LATITUDE

autumnal equinox (first point of Libra), one of two points of intersection between celestial equator and ecliptic

An observer on Earth can view, at best, only half of the celestial sphere at any instant (assuming a cloudless sky and unobstructed horizon). The other half is obscured by Earth’s bulk. In fact, for an observer at either of Earth’s poles, a specific half of the celestial sphere is always overhead, while the other half is never visible. For observers at other latitudes, Earth’s rotation continually brings new parts of the celestial sphere into view and hides others. This means, for example, that over the course of a night, an observer at a latitude of 60°N or 60°S can see up to three-quarters of the celestial sphere for at least some of the time; and an observer at the equator can see every point on the celestial sphere at some time.

north celestial pole

south celestial pole lies below Earth’s South Pole

MOTION AT NORTH POLE

W

north celestial pole S E

Earth

N circumpolar area

I N TRO D UC TI O N

KEY stars always visible stars never visible

celestial equator

OBSERVER AT EQUATOR

OBSERVER AT NORTH POLE

OBSERVER AT MID-LATITUDE

For a person on the equator, Earth’s rotation brings all parts of the celestial sphere into view for some time each day. The celestial poles are on the horizon.

For this observer, the northern half of the celestial sphere is always visible, and the southern half is never visible. The celestial equator is on the observer’s horizon.

For this observer, a part of the celestial sphere is always visible, a part is never visible, and Earth’s rotation brings other parts into view for some of the time each day.

W

S E

stars sometimes visible

MOTION AT MID-LATITUDE

At mid-latitudes, most stars rise in the east, cross the sky obliquely, and set in the west. Some (circumpolar) objects never rise or set but circle the celestial pole. MOTION AT EQUATOR

position of observer observer’s horizon

N

At the poles, all celestial objects seem to circle the celestial pole, directly overhead. The motion is counterclockwise at the North Pole, clockwise at the south.

W S

N E

At the equator, stars and other celestial objects appear to rise vertically in the east, move overhead, and then fall vertically and set in the west.

THE CELESTIAL SPHERE

63

DAILY SKY MOVEMENTS As the Earth spins, all celestial objects move across the sky, although the movements of the stars and planets become visible only at night. For an observer in mid-latitudes, stars in polar regions of the celestial sphere describe a daily circle around the north or south celestial pole. The Sun, Moon, planets, and the remaining stars rise along the eastern horizon, sweep in an arc across the sky, and set in the west. This motion has a tilt to the south (for observers in the Nothern Hemisphere) or to the north (Southern Hemisphere)— the lower the observer’s latitude, the steeper the tilt. Stars have fixed positions on the sphere, so the pattern of their movement EQUATORIAL NIGHT zenith at repeats with great precision once 6:00 PM From the equator, almost the sunset every sidereal day (see p.66). The whole of the celestial sphere can be seen for some of the planets, Sun, and Moon always move time during one night. The on the celestial sphere, so the Sun’s glow obscures only a period of repetition differs from small part of the sphere. that of the stars. afterglow from sunset obscures stars

CIRCUMPOLAR STARS

Stars in the polar regions of the celestial sphere describe perfect partcircles around the north or south celestial pole during one night, as shown by this longexposure photograph.

YEARLY SKY MOVEMENTS As Earth orbits the Sun, the Sun seems to move against the background of stars. As the Sun moves into a region of the sky, its glare washes out fainter light from that part, so any star or other object there temporarily becomes difficult to view from anywhere on Earth. Earth’s orbit also means that the part of the celestial sphere on the opposite side to Earth from the Sun—that is, the part visible in the middle of the night— changes. The visible part of the sky at, for example, midnight in June, September, December, and March is significantly different—at least for observers at equatorial or Sun mid-latitudes on Earth. Earth at Northern Hemisphere’s winter solstice (December 21/22) hemisphere visible from equator at midnight on the winter solstice

Earth at Northern Hemisphere’s summer solstice (June 21)

Earth’s axis of rotation

JUNE AND DECEMBER SKIES

At opposite points of Earth’s orbit, an observer on the equator sees exactly opposite halves of the celestial sphere at midnight.

Earth’s orbit

hemisphere visible from equator at midnight on the summer solstice

MIDNIGHT

pre-dawn glow obscures stars

zenith at midnight

North Pole, around which Earth rotates

observer’s view at midnight is unobscured observer’s view after sunset is obscured in the west by the Sun

Earth’s rotation

6:00 AM

zenith at dawn

observer’s view before sunrise is obscured in the east by the Sun

EXPLORING SPACE

ARISTOTLE’S SPHERES sphere of Until the 17th century ad, the idea of a “fixed” stars celestial sphere surrounding Earth was not just a convenient fiction— many people believed it had a physical reality. Such beliefs date back to a model of the universe developed by the Greek philosopher Aristotle (384–322 bc) and elaborated by the astronomer Ptolemy (ad 85–165). Aristotle placed Earth stationary at the universe’s center, surrounded by several transparent, concentric spheres to which the stars, planets, Sun, and Moon were attached. Ptolemy supposed that the spheres ARISTOTELIAN MODEL OF THE UNIVERSE rotated at different speeds around Stars are fixed to the outer sphere. Working inward, Earth, so producing the observed the other spheres around Earth carry Saturn, Jupiter, motions of the celestial bodies. Mars, the Sun, Venus, Mercury, and the Moon.

north celestial pole

celestial meridian—the line of 0° right ascension

angle of declination (45°), above celestial equator

star position

CELESTIAL COORDINATES

45°

celestial equator

first point of Aries (vernal equinox point) is the origin for right-ascension measurements

angle of right ascension (1 hour, or 15°)

I N TR OD U CT I ON

Using the celestial sphere concept, astronomers can record and find the positions of stars and other celestial objects. To define an object’s position, astronomers use a system of coordinates, similar to latitude and longitude on Earth. The coordinates are called declination and right ascension. Declination is measured in degrees and arc-minutes (60 arc-minutes = 1 degree/1°) north or south of the celestial equator, so it is equivalent to latitude. Right ascension, the equivalent of longitude, is the angle of an object to the east of the celestial meridian. The meridian is a line passing through both celestial poles and a point on RECORDING A STAR’S POSITION the celestial equator called the first point of Aries or The measurement of a star’s position vernal equinox point (see p.65). An object’s right on the celestial sphere is shown here. ascension can be stated in degrees and arc-minutes This star has a declination of about 45° or in hours and minutes. One hour is equivalent to (sometimes written +45°) and a right 15°, because 24 hours make a whole circle. ascension of about 1 hour, or 15°.

64

THE VIEW FROM EARTH

Sun in midsummer

CELESTIAL CYCLES

Sun in midwinter Sundial

TO AN OBSERVER ON EARTH, celestial

events occur within the context of cycles determined by the motions of Earth, The Sun 104–107 Sun, and Moon. These cycles provide us with some of our Earth 124–35 basic units for measuring time, such as days and years. The Moon 136–49 They include the apparent daily motions of all celestial Mapping the sky 348–53 objects across the sky, the annual apparent movement of the Sun against the celestial sphere, the seasonal cycle, and the monthly cycle of lunar phases. Other related cycles produce the dramatic but predictable events known as lunar and solar eclipses.

62–63 The celestial sphere

THE SUN’S ANALEMMA MYTHS AND STORIES

ASTROLOGY AND THE ECLIPTIC Astrology is the study of the positions and movements of the Sun, Moon, and planets in the sky in the belief that these influence human affairs. At one time, when astronomy was applied mainly to devising calendars, astronomy and astrology were intertwined, but their aims and methods have now diverged. Astrologers pay little attention to constellations, but measure the positions of the Sun and planets in sections of the ecliptic that they call “Aries” and “Taurus,” for example. However, these sections no longer match the constellations of Aries, Taurus, and so on. STARGAZER

This 17th-century illustration, taken from a treatise written in India on the zodiac, depicts a stargazer using an early form of mounted telescope.

Deneb path of north celestial pole across the sky every 25,800 years Vega, pole star in AD 15000

25,800-year wobble of Earth’s axis

I N TRO D UC TI O N

angle of tilt remains the same throughout precession

rotation of Earth around its axis

Alderamin, pole star in AD 8000

THE SUN’S CELESTIAL PATH As the Earth travels around the Sun, to an observer on Earth the Sun seems to trace a path across the celestial sphere known as the ecliptic. Because of the Sun’s glare, this movement is not obvious, but the Sun moves a small distance each day against the background of stars. The band of sky extending for 9 degrees (see p.63) on either side of the Sun’s path is called the zodiac and incorporates parts or all of 24 constellations (see p.72). Of these, the Sun passes through 13 constellations, of which 12 form the “signs of the zodiac,” well-known to followers of astrology (see panel, left). The Sun spends a variable number of days in each of these 13 constellations. However, the Sun currently passes through each constellation on dates very different from traditional astrological dates. For example, someone born between March 21 and April 19 is said to have the sign Aries, although the Sun currently passes through Aries between April 19 and May 23. This disparity is partly caused by a phenomenon called precession.

To produce this image, the Sun was photographed, above a sundial, at the same time of day on 37 occasions throughout one year. The vertical change in its position is due to Earth’s tilt. The horizontal drift is due to Earth changing its speed on its elliptical orbit around the Sun. The resulting figureeight pattern is called an analemma.

PRECESSION The Earth’s axis of rotation is tilted from the ecliptic plane by 23.5°. The tilt is crucial in causing seasons (see opposite). At present, the axis points at a position on the northern celestial sphere (the north celestial pole) close to the star Polaris, but this will not always be so. Like a spinning top, Earth is Polaris (current executing a slow “wobble,” which alters the direction of its north Pole Star) axis over a 25,800-year cycle. The wobble, called precession, is caused by the gravity of the Sun and Moon. It also causes the south celestial pole, the celestial equator, and two other Earth’s axis reference points on the celestial sphere, called the equinox of rotation points, to change their locations gradually. The coordinates of stars and other “fixed” EARTH’S WOBBLE Precession causes Earth’s spin objects, such as galaxies (see p.63), therefore equator axis to trace out the shape of a change, so astronomers must quote them cone. As it does so, both the north and south celestial poles trace out according to a standard “epoch” of around 50 years. The current standard was exactly circular paths on the celestial sphere, in a 25,800-year cycle. correct on January 1, 2000.

ISLAMIC ZODIAC

This Islamic depiction of part of the celestial sphere includes several constellations that are also well-known zodiacal “star signs,” such as Scorpius and Leo. The illustration decorates a 19th-century manuscript from India that brought together Islamic, Hindu, and European knowledge of astronomy. MIDNIGHT SUN

This multiple-exposure photograph (below) shows the path of the Sun around midnight near the summer solstice in Iceland. Since the photograph was taken in polar latitudes, Earth’s angle of tilt ensures the Sun does not set.

CELESTIAL CYCLES

Ophiuchus, the 13th constellation in the zodiac

Virgo Libra

direction of Sun’s movement

Sun

THE ZODIAC

first point of Libra, or point of the Northern Hemisphere’s autumnal equinox Leo Cancer

Scorpius

Shown here is the band of the celestial sphere known as the zodiac. The band lies on either side of the ecliptic—the Sun’s apparent circular path through the sky. As Earth orbits the Sun, the Sun traces out this path month by month. The zodiac includes the 12 star-sign constellations plus a 13th constellation, Ophiuchus, that crosses the ecliptic between Scorpius and Sagittarius. As well as the Sun, the celestial paths of the Moon and planets (except Pluto) are restricted to the zodiac.

Earth’s rotation around its axis

Earth’s equator

65

Gemini

Taurus Aries—now far from the “first point of Aries”, due to the precession of Earth’s poles (see opposite)

Sagittarius ECLIPTIC The apparently circular path of the Sun on the celestial sphere

Capricornus

Aquarius

THE SEASONS

Pisces first point of Aries, or point of the Northern Hemisphere’s vernal equinox

Earth on December 21 or 22, the Northern Hemisphere’s winter solstice

Earth on March 20 or 21, the Northern Hemisphere’s vernal or spring equinox

midday sun overhead at Tropic of Cancer

midday sun overhead at Tropic of Capricorn

Sun Earth’s orbit

Earth on June 21 or 22, the Northern Hemisphere’s summer solstice

Earth on September 22 or 23, the Northern Hemisphere’s autumnal equinox

23.5° angle of tilt Tropic of Cancer, 23.5°N

axis of spin

SUNLIGHT INTENSITY

solar radiation

Tropic of Capricorn, 23.5°S

direction of Earth’s spin

The intensity of solar radiation is greatest within the tropics. Toward the poles, the Sun’s rays impinge at an oblique angle. They must pass through a greater thickness of atmosphere, and they are spread over a wider area of ground.

I N TR OD U CT I ON

SOLSTICES AND Earth’s orbit around the Sun takes 365.25 days and provides a key unit of EQUINOXES At the solstices, in time, the year. Earth’s seasons result June and December, from the tilt of its axis relative to its one hemisphere has its longest day, the orbit. Due to Earth’s tilt, one or other other its shortest. of its hemispheres is normally pointed At the equinoxes, in toward the Sun. The hemisphere that March and September, tilts toward the Sun receives more the lengths of day sunlight and is therefore warmer. Each and night are equal year, the Northern Hemisphere reaches everywhere on Earth. its maximum tilt toward the Sun around June 21—summer solstice in the Northern Hemisphere and winter solstice in the Southern Hemisphere. For some time around this date, the north polar region is sunlit all day, while the south polar region is in darkness. Conversely, around December 21, the situation is reversed. Between the solstices are the equinoxes, when Earth’s axis is broadside to the Sun and the periods of daylight and darkness are equal for all points on Earth. Earth’s tilt also defines the tropics. The Sun is overhead at midday on the Tropic of Cancer (23.5°N) around June 21, above the Tropic of Capricorn (23.5°S) around December 21, and directly above the equator at midday during the equinoxes.

CELESTIAL EQUATOR A projection of Earth’s own equator onto the celestial sphere

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THE VIEW FROM EARTH

MEASURING DAYS SOLAR TIME

Solar time is the way of gauging time from the Sun’s apparent motion across the sky, as measured by a sundial. One solar day is subdivided into 24 hours.

Every day, Earth rotates once, and most locations on its surface pass from sunlight to shadow and back, producing the day–night cycle. However, there are two possible definitions for what constitutes a day, and only one of these, the solar day, lasts for exactly 24 hours. A solar day is defined by the apparent movement of the Sun across the sky produced by APRIL 1, 8:00 P.M. Earth’s rotation. It is the length of time the Sun takes to return to its highest point in the sky from the same point the previous day. The other type of day, the sidereal day, is defined by Earth’s rotation relative to the stars. It is the length of time a star takes to return to its highest point in the sky on successive days. A sidereal day is 4 minutes shorter than a solar day.

APRIL 15, 8:00 P.M.

APRIL 8, 8:00 P.M.

SIDEREAL TIME

The distinctive constellation Orion (see pp.390–91), here pictured as if from 50°N, appears lower in the sky at the same solar time each day, as the daily 4-minute difference between solar and sidereal time mounts up. direction of a distant star, against which sidereal time can be measured

SOLAR AND SIDEREAL DAY

The disparity between solar and sidereal days results from Earth’s orbit and rotation. After rotating once relative to the stars, Earth must rotate a little farther to bring the Sun back to the same point in the sky. Sun

Earth’s orbit

noon on first day Earth’s rotation

second noon in solar time

second noon in sidereal time (4 minutes earlier than solar time)

MEASURING MONTHS

6. last quarter 7. waning crescent

5. waning gibbous

8. new moon

4. full moon

sunlight

3. waxing gibbous

1. waxing crescent

I NT RO DU C TI ON

2. first quarter

1. WAXING CRESCENT

2. FIRST QUARTER

3. WAXING GIBBOUS

4. FULL MOON

The concept of a month is based on the Moon’s orbit around Earth. During each of the Moon’s orbits, the angle between Earth, the Moon, and the Sun continuously changes, giving rise to the Moon’s phases. The phases cycle through new moon (when the Moon is between Earth and the Sun), crescent, quarter, and gibbous, to full moon (when the Earth lies between the Moon and the Sun). A complete cycle of the Moon’s phases takes 29.5 solar days and defines a lunar month. However, Earth’s progress around the Sun complicates the expression of a month, just as it confuses the measurement of a day. The Moon in fact takes only 27.3 days to orbit Earth with reference to the background stars. Astronomers call this period a sidereal month. The disparity results because Earth’s progress around the Sun alters the angles between the Earth, Sun, and Moon. After CHANGING ANGLES During each lunar orbit, the one full orbit of Earth (a sidereal angle between Earth, the Moon, month), the Moon must orbit and the Sun changes. The part a bit farther to return to its of the Moon’s sunlit face seen original alignment with Earth by an observer on Earth and the Sun (a lunar month). changes in a cyclical fashion.

5. WANING GIBBOUS

6. LAST QUARTER

7. WANING CRESCENT

8. NEW MOON

CELESTIAL MAIN_TEMPLATE CYCLES

LUNAR ECLIPSES

MYTHS AND STORIES

EVIL PORTENTS

As the Moon orbits the Earth, it occasionally moves into Earth’s shadow—an occurrence called a lunar eclipse—or blocks sunlight from reaching a part of Earth’s surface—a solar eclipse. Eclipses do not happen every month, because the plane of the Moon’s orbit around Earth does not coincide with the plane of Earth’s orbit around the Sun. Nevertheless, an eclipse of some kind occurs several times each year. Lunar eclipses are common, occurring two or three times a year, always during a full moon. Astronomers classify lunar eclipses into three different types. In a penumbral eclipse, the Moon passes through Earth’s penumbra (part-shadow), leading to only a slight dimming of the Moon. Earth In a partial eclipse, a portion of the Moon passes through Earth’s umbra (full shadow), while in a total eclipse the whole Moon passes through the umbra. sunlight

Astronomers have predicted eclipses reliably since about 700 bc, but that has not stopped doomsayers and astrologers from reading evil omens into these routine celestial events. They have often prophesied disasters associated with eclipses, and although they meet with no more than occasional success, some people listen. The Incas below, for instance, are pictured as awestruck by an eclipse, in a European atlas of 1827. Eclipses may not be useful for predicting the future, but accounts of past eclipses are of great value to today’s historians, who can calculate the dates of events with great precision if the historical accounts include records of eclipses.

TOTAL LUNAR ECLIPSE

This composite photograph shows stages of a total lunar eclipse. The moon appears red at the eclipse’s peak (bottom left), because a little red light is bent toward it by refraction in Earth’s atmosphere. only a slight darkening of the Moon occurs in the light outer shadow

umbra (inner, darker shadow)

the Moon is darkest within the umbra

MECHANICS OF A LUNAR ECLIPSE

Earth’s shadow consists of the penumbra, within which some sunlight is blocked out, and the umbra, or full shadow. In a total eclipse, the Moon passes through the penumbra, the umbra, and then the penumbra again.

SOLAR ECLIPSES

penumbra (outer, paler shadow)

full moon

ECLIPSE SEQUENCE

An eclipse of the Sun occurs when the Moon blocks sunlight from reaching part of the Earth. During a total eclipse, viewers within a strip of Earth’s surface, called the path of totality, witness the Sun totally obscured for a few moments by the Moon. Outside this area is a larger region where viewers see the Sun only partly obscured. More common are partial eclipses, which cause no path of totality. A third type of solar eclipse is the annular eclipse, occurring when the TOTALITY PATHS Moon is farther from Earth than average, so that The part of Earth’s its disk is too small to cover the Sun’s disk totally. surface over which the At the peak of an annular eclipse, the Moon looks Moon’s full shadow will like a dark disk inside a narrow ring of sunlight. sweep during a total solar eclipse, called the Solar eclipses happen two or three times a year, path of totality, can be but total eclipses occur only about once every predicted precisely. 18 months. During the period of totality, the Sun’s Below are the paths for corona (its hot outer atmosphere) becomes visible. eclipses up to 2015.

This multiple exposure photograph depicts more than 20 stages of a total solar eclipse, seen in Mexico in 1991. At the center can be seen the corona around the fully eclipsed Sun.

BAILY’S BEADS

At the beginning and end of a total solar eclipse, the Moon’s rough, cratered surface breaks a thin slice of Sun into patches of light called “Baily’s Beads.”

20 0 8 ust 1,

20

,2 01 5

Aug

67

rch Ma

Moon

20 0

Earth

sunlight

9, h2 Marc 06 20 umbra (inner, darker shadow)

2 November 11, 201

MOON SHADOW

The shadow cast by the Moon during a total solar eclipse consists of the central umbra (associated with the area of totality) and the penumbra (area of partial eclipse).

area of partial eclipse

I N TR OD U CT I ON

11, 20 10 July

5

9

8,

area of totality

July 22 ,2

00

ri l Ap

Nov em be r3 , 2 01 3

penumbra (outer, paler shadow)

68

THE VIEW FROM EARTH

PLANETARY MOTION THE PLANETS IN THE SOLAR SYSTEM

are much closer to Earth than are the stars, so as they orbit Naked-eye astronomy 76–77 the Sun they appear to wander across the starry Binocular astronomy 80–81 background. This sky motion is influenced by Using the sky guides 428–29 Earth’s own solar orbit, which changes the point of view of Earth-bound observers. The planets closest to Earth move around on the celestial sphere more rapidly than the more distant planets; this is partly due to perspective and partly because the closer a planet is to the Sun, the faster is its orbital speed.

64–67 Celestial cycles

INFERIOR AND SUPERIOR PLANETS In terms of their motions in the sky as seen from Earth, the planets are divided into two groups. The inferior planets, Mercury and Venus, are those that orbit closer to the Sun than does Earth. They never move far from the Sun on the celestial sphere—the greatest angle by which the planets stray from the Sun (called their maximum elongation) is 28° for Mercury and 45° for Venus. Because they are close to Earth and orbiting quickly, both planets move rapidly against the background stars. They also display phases, like the Moon’s (see p.66), because there is some variation in the angle between Earth, the planet, and the Sun. All the other planets, from Mars outward, are called superior planets. These are not “tied” to the Sun on the celestial sphere, and so can be seen in the middle of the night. Apart from Mars, the superior planets are too far from Earth to display clear phases, and they move slowly on the celestial sphere—the farther they are from the Sun, the slower their movement.

ALWAYS NEAR THE SUN

The Moon and Venus appear close together here in the dawn sky. Venus is only ever visible in the eastern sky for up to a few hours before dawn, or in the western sky after dusk—it is never seen in the middle of the night. This is because it orbits closer to the Sun than Earth and so never strays far from the Sun in the sky. superior conjunction—planet is in line with the Sun, on its far side

superior conjunction of inferior planet; planet appears “full,” but lies on the opposite side of the Sun

JOHANNES KEPLER The German astronomer Johannes Kepler (1571–1630) discovered the laws of planetary motion. His first law states that planets orbit the Sun in elliptical paths. The next states that the closer a planet comes to the Sun, the faster it moves, while his third law describes the link between a planet’s distance from the Sun and its orbital period. Newton used Kepler’s laws to formulate his theory of gravity.

I N TRO D UC TI O N

maximum western elongation; planet appears as crescent in morning sky

maximum eastern elongation; planet appears as crescent in evening sky

VIEWING THE PLANETS

inferior planet’s

The terms defined orbit here are used to describe specific juxtapositions of Earth, the Sun, and planets. These affect the phase, brightness and size, and times of visibility of planets in Earth’s skies.

path of Mars across sky

Earth

opposition of superior planet (planet appears large and is visible all night)

inferior conjunction— inferior planet lies directly between Earth and Sun; it is in “new” phase and is not visible from Earth

RETROGRADE MOTION

ecliptic plane

Mars’s orbit inclined relative to ecliptic plane

superior planet’s orbit

Sun Mars

Earth’s orbit

Earth

The planets generally move through the sky from west to east against the background of stars, night by night. However, periodically, a planet moves from east to west for a short time—a phenomenon called retrograde motion. Retrograde motion is an effect of changing perspective. Superior planets such as Mars show retrograde motion when Earth “overtakes” the other planet at opposition (when Earth moves between the superior planet and the Sun). The inferior planets Mercury and Venus show retrograde motion on either side of ZIGZAG ON THE SKY inferior conjunction. In retrograde motion, a planet They overtake Earth may perform a loop or a zigzag on as they pass between the sky, depending on the angle Earth and the Sun. of its orbit relative to Earth’s.

MARTIAN LOOP-THE-LOOP

This composite of photographs taken over several months shows a retrograde loop in Mars’s motion against the background stars. The additional short dotted line is produced by Uranus.

69

ALIGNMENTS IN THE SKY Because all the planets orbit the Sun roughly in the same plane (see pp.102–03), they never stray from the band in the sky called the zodiac (see p.65). It is not uncommon for several of the planets to be in the same part of the sky at the same time, often arranged roughly in a line. Such events, called planetary conjunctions, are of no deep significance, but can be a spectacular sight. Another type of alignment, called a transit, occurs when an inferior planet comes directly between Earth and the Sun, passing across the Sun’s disk. A pair of Venus transits, eight years apart, occurs about once a century or so, while Mercury transits happen about 12 times a century. In earlier times, these transits allowed astronomers to obtain more accurate data on distances in the solar system. A final type of alignment is an occultation—one celestial body passing in front of, and hiding, another. Occultations VENUS’S PATH ACROSS THE SUN’S DISK of one planet by another, such as Venus occulting This composite photograph of Venus’s 2004 Jupiter, occur only a few times a century; in contrast, transit spans just over five hours. During this time, astronomers gathered data on the Sun’s occultations of one or other of the bright planets by changing light to use as a model to look for the Moon occur 10 or 11 times a year. Earth-sized planets orbiting other stars. Jupiter

TRANSIT OF VENUS

This photograph of the 2004 Venus transit shows our nearest planetary neighbor as a dark circle close to the edge of the Sun’s disk. This was the first Venus transit since 1882. Another occurred in 2012, but no more are expected until 2117.

OCCULTATION OF JUPITER BY THE MOON

This occultation occurred on January 26, 2002, and was visible above a latitude of 55°N. Here, the planet sinks out of sight beyond the dark far wall of the lunar crater Bailly. Occultations by the Moon tend to run in series, when for a period the planet and Moon wander into alignment as seen from Earth. An occultation then occurs approximately every sidereal month, until eventually the planet and Moon drift out of alignment again.

NICOLAUS COPERNICUS Born in Torun, Poland, Copernicus (1473–1543) studied theology, law, and medicine at university. In 1503, he became the canon of Frauenberg Cathedral. This post provided financial security and left him plenty of time to indulge his passion for astronomy. He described his idea of a Suncentered universe in his book On the Revolution of the Heavenly Spheres, published in the year of his death.

Saturn Mars

At first, Copernicus’s revolutionary new idea made little impact. It was only after the telescopic observations of Galileo Galilei and the discovery of the laws of planetary motion by Johannes Kepler (see panel, opposite) that it was finally accepted.

The conjunction shown here, involving all five naked-eye planets, was visible after sunset for several evenings in April 2002. Although the planets appear close, they are separated by tens or hundreds of millions of miles.

Venus

Mercury

This map made by Andreas Cellarius demonstrates the Copernican theory of Earth and the other planets circling the Sun, with the zodiac stars beyond.

I N TR OD U CT I ON

COPERNICAN MAP PLANETARY CONJUNCTION, APRIL 2002

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THE VIEW FROM EARTH

STAR MOTION AND PATTERNS STARS MAY SEEM TO BE FIXED

to the celestial sphere, but in fact their positions are changing, albeit very slowly. There Stars 232–33 are two parts to this motion: a tiny, yearly wobble of a star’s The history of constellations 346–47 position in the sky, called parallax shift; and a continuous Mapping the sky 348–53 directional motion, called proper motion. To record the motion of stars, and properties such as their color and brightness, each star needs a name. Naming systems and catalogs have their roots in the constellations, which were invented to describe the patterns formed by stars in the sky. 62–63 The celestial sphere

EXPLORING SPACE

HIPPARCOS Hipparcos is a European Space Agency satellite that between 1989 and 1993 performed surveys of the stars. Its name is short for High Precision Parallax Collecting Satellite and was chosen to honour the Greek astronomer Hipparchus. Its mission has resulted in two catalogs. The Hipparcos catalog records the position, parallax, proper motions, brightness, and color of over 118,000 stars, to a high level of precision. The Tycho catalog records over 1 million stars with measurements of lower accuracy.

PARALLAX SHIFT

Although at first glance they all look white, stars differ in their colors—that is in the mixture of light wavelengths they emit. This is a long-exposure photograph of the bright stars of Orion, taken while changing the camera’s focus. Each star looks white when sharply focused, but when its light is spread out, its true color is revealed.

Parallax shift is an apparent change in the position of a relatively close object against a more distant background as the observer’s location changes. When an observer takes two photographs of a nearby star from opposite sides of Earth’s orbit around the Sun, the star’s position against the background of stars moves slightly. When the observer measures the size of this shift, knowing the diameter of Earth’s orbit, she or he can calculate the star’s distance using trigonometry. Until recently, this technique was limited to stars within a few hundred lightyears of Earth, because the shifts of distant stars were too small to measure accurately. However, by using accurate instruments carried in satellites, much greater precision is possible: those carried in the Hipparcos satellite (see panel, left) have allowed calculation of star distances up to a few thousand light-years from Earth. For more distant stars, the shift is vanishingly small, and so other methods must be used for estimating their distances. parallax shift of nearby Star A

position of Earth in July

HIPPARCOS SATELLITE

The satellite spun slowly in space, scanning strips of the sky as it rotated. It measured the motion of each star about 100 to 150 times.

Star A

Star B

Sun

position of Earth in January

parallax angle

smaller parallax shift of Star B

PROPER MOTION OF STARS

I NT ROD U C TI O N

STAR COLORS

All stars in our galaxy are moving at different velocities relative to the solar system, to the galactic center, and to each other. This motion gives rise to an apparent angular movement across the celestial sphere called a star’s proper motion—measured in degrees per year. Most stars are so distant that their proper motions are negligible. About 200 have proper motions of more than 1 arc-second a year—or 1 degree of angular movement in 3,600 years. Barnard’s star (see p.381) has the fastest proper motion, moving at 10.3 arc-seconds per year. It takes 180 years to travel the diameter of a full moon in the sky. If astronomers know both the proper motion of a star and its distance, they can calculate its transverse CHANGING SHAPE velocity relative to Earth—that is, its The shape of the star pattern velocity at right angles to the line of known as the Big Dipper sight from Earth. The other component gradually changes due to the proper motions of its stars. of a star’s velocity relative to Earth is Five stars are moving in called its radial velocity (its velocity unison as a group, but the toward or away from Earth), measured two stars on the ends are by shifrs in the star’s spectrum (see p.35). moving independently.

THE BIG DIPPER IN 100,000 BC

THE BIG DIPPER IN AD 2000

THE BIG DIPPER IN AD 100,000

MEASURING DISTANCE USING PARALLAX

When Star A is observed from opposite sides of Earth’s orbit, its apparent shift in position is greater than that of more distant Star B. From the shift, an observer can calculate the parallax angle between the star and the two positions of Earth. The star’s distance can be determined from this angle.

STAR MOTION AND PATTERNS

71

THE BRIGHTNESS OF STARS A star’s brightness in the sky depends on its distance from Earth and on its intrinsic brightness, which is related to its luminosity (the amount of energy it radiates into space per second, see p.233). To compare how stars would look if they were all at the same distance, astronomers use a measure of intrinsic brightness called the absolute magnitude scale. This scale uses high positive numbers to denote dim stars and negative numbers for the brightest ones. A star’s brightness as seen from Earth, on the other hand, is described by its apparent magnitude. Again, the smaller the number of a star’s apparent magnitude, the brighter the star. Stars with an apparent magnitude of +6 are only just detectable to the naked eye, whereas the apparent magnitude of most of the 50 brightest stars is between +2 and 0. The four brightest (including the brightest star of all, Sirius) have negative apparent magnitudes. Betelgeuse

Bellatrix

INTRINSICALLY BRIGHT STAR

The stars Betelgeuse and Bellatrix mark the shoulders of Orion. Betelgeuse is noticeably brighter (apparent magnitude 0.45) than Bellatrix (1.64), despite being twice as distant. It is a red, high-luminosity supergiant, whereas Bellatrix is a much less luminous giant.

NEARBY BRIGHT STAR

In the constellation Centaurus, the triple star system Alpha (α) Centauri is a little brighter (apparent magnitude –0.01) than the binary star Hadar, or Beta (β) Centauri (0.61). The reason for Alpha Centauri’s brightness is its proximity— it is our closest stellar neighbor. The blue giant stars that make up Hadar are much more Iuminous than the stars in Alpha Centauri, but they are about 120 times farther away. Alpha Centauri

Hadar (Beta Centauri)

when the light reaches the larger sphere, it is spread over four times the area (the square of the distance, or 2x2)

light from the star spreads over this area of the smaller sphere

star

The apparent brightness of a star drops in proportion to the square of its distance from the observer—a rule called the inverse square law. This happens because light energy is spread out over a progressively larger area as it travels away from the star.

the larger sphere has twice the radius of the smaller sphere

I N TR OD U C TI O N

THE INVERSE SQUARE RULE

72

THE VIEW FROM EARTH

CONSTELLATIONS Since ancient times, people have seen imaginary shapes among groups of stars in the night sky. Using lines, they have joined the stars in these groups to form figures called constellations and named these constellations after the shapes they represent. Each constellation has a Latin name, which in most cases is either that of an animal, for example, Leo (the lion), an object, such as Crater (the cup), or a mythological character, such as Hercules. Some constellations, such as Orion (the Hunter), are easy to recognize; others, such as Pisces (the Fishes), are less distinct. Since 1930, an internationally agreed system has divided the celestial sphere into 88 irregular LOST CONSTELLATIONS Some constellations have proved short-lived. areas, each containing one of these figures. In In the 19th century, Felis, the cat, was fact, from an astronomical point of view, the incorporated into what is now part of the word “constellation” is now applied to the area constellation of Hydra. It appeared on several of the sky containing the figure rather than to star charts but was not officially adopted. the figure itself. All stars inside the boundaries of a constellation area belong to that constellation, even if they are not connected to the stars that produce the constellation figure. Within some constellations are some smaller, distinctive groups of stars known as asterisms; these include Orion’s belt (a line of three bright stars in Orion) and the Big Dipper (a group of seven stars in the constellation Ursa Major). A few asterisms cut across constellation Mizar boundaries. For example, most of Alkaid Alioth the “Square of Pegasus” asterism is in Pegasus, but one of its Megrez corners is in Andromeda. portion of the celestial sphere

STAR CHART

constellation borders usually follow lines of right ascension and declination

This star chart of Ursa Major (the Great Bear) shows the constellation figure (the pattern of lines joining bright stars) and labels many of the stars, as well as objects such as galaxies, lying within the constellation’s boundaries.

70°

northern border of constellation

14h 60° 13h

Messier object—a nebulous object, such as a galaxy or nebula, catalogued by Messier (see panel, opposite) to avoid confusion while comet-hunting Dubhe Phad

LINE-OF-SIGHT EFFECT

A star pattern such as the Plough in Ursa Major is a twodimensional view of what may be a widely-scattered sample of stars. The stars might seem to lie in the same plane, but they are at different distances from Earth. If we could view the stars from elsewhere in space, they would form a totally different pattern.

40°

pattern of the Plough in the sky

Merak line of declination (for calculating celestial coordinates)

Earth

40

60

80

100

120

140 30°

DISTANCE IN LIGHT YEARS

EXPLORING SPACE

BAYER’S SYSTEM

I N TRO D U CT I ON

Johann Bayer ascribed Greek letters to the stars in a constellation, roughly in order of decreasing brightness. Regulus, the brightest star in the constellation of Leo, was given the name Alpha (α) BAYER’S MAP OF Leonis, the second brightest URSA MAJOR (Denebola) was called Beta (β) The seven stars of Leonis, and so on. In some cases, the Plough can be seen Bayer used other ordering in the upper left area systems. The Plough in Ursa of this chart from Bayer’s Uranometria. Major is lettered by following the stars from west to east.

50°

NAMING THE STARS Most of the brighter stars in the sky have ancient names of Babylonian, Greek, or Arabic origin. The name Sirius, for example, comes from a Mizar Greek word meaning “scorching.” Alioth 79 The first systematic naming of stars 77 ζ ε Alkaid was introduced by Johann Bayer in 85 1603 (see panel, left, and p.347). η Bayer distinguished up to 24 stars in each constellation by labeling them with Greek letters, after which he resorted to using Roman lower case letters, a to z. In 1712, English astronomer John Flamsteed (1646– 1719) introduced another system, in which stars are numbered in order of their right ascension (see p.63) from west to east across their constellation. Stars are usually named by linking their Bayer letter or Flamsteed number with the genitive form (possessive case) of the constellation name— so 56 Cygni denotes the star that is 56th closest to the western edge of the constellation Cygnus. Since the 18th century, numerous further catalogs have identified and numbered many more faint stars, and specialized systems have been devised for cataloguing variable, binary, and multiple stars.

Dubhe 50

α

Megrez 69

Merak 45

δ Phad 64

β

γ

SYSTEMS OF BAYER AND FLAMSTEED

This photo of the Plough in Ursa Major shows the ancient name of each star, its Bayer designation, and its Flamsteed number. For example the star Alkaid can also be called Eta (η) Ursae Majoris (Bayer) or 85 Ursae Majoris (Flamsteed).

12h

STAR MOTION AND PATTERNS

73

9h 10h 11h

western border of constellation

line of right ascension (for calculating celestial coordinates)

Flamsteed number, denoting place of star in Flamsteed’s naming system

CATALOGS OF NEBULOUS OBJECTS Besides individual stars, various other types of object, such as star clusters, nebulae, and galaxies, have practically fixed positions on the celestial sphere. Most of these objects appear as no more than hazy blurs in the sky, even through a telescope. The first person to catalog such objects was a French astronomer, Charles Messier (see panel, below), in the 18th century. He compiled a list of 110 hazy objects, though none of these are from the southern polar skies—that is because Messier carried out his observations from Paris, and anything in declination below 40°S was below his horizon. In 1888, a much larger catalog called the New General Catalog of Nebulae and Star Clusters (NGC) was published, and this was later expanded by what is called the Index Catalog (IC). To this day, the NGC and IC are important catalogs of nebulae, star clusters, and galaxies. Their current versions cover the entire sky and provide data on more than 13,000 objects, all identified by NGC or IC numbers. In addition, several hundred specialized astronomical NGC 2841, A SPIRAL GALAXY catalogs are in use, covering different types of objects, parts of the sky, and regions of the electromagnetic spectrum. Many catalogs are now maintained as computer databases accessible over the Internet. NEW GENERAL CATALOG

line joining two of the stars forming the constellation figure

Greek letter, denoting place of star in Bayer’s naming system

More than 150 New General Catalog (NGC) objects lie within the constellation Ursa Major. Two are shown here, both spiral galaxies in a region around the Great Bear’s forelegs, not far from Theta (θ) Ursae Majoris. NGC 2841 has delicate, tightly wound arms, within which astronomers have recorded many supernovae explosions. NGC 3079 has an active central region, from which rises a lumpy bubble of hot gas, 3,500 light-years wide, driven by star formation. NGC 3079, A SPIRAL GALAXY VIEWED EDGE-ON

THE MESSIER CATALOG

Messier’s catalog includes 57 star clusters, 40 galaxies, 1 supernova remnant (the Crab Nebula). 4 planetary nebulas, 7 diffuse nebulas, and 1 double star. Of these Messier objects, 8 lie in the constellation of Ursa Major, of which five are shown here. Each is denoted by the latter M followed by a number. The planetary nebula M97 is also called the Owl Nebula. Galaxies M81 and M82 are neighbors in the sky and can be viewed simultaneously with a good pair of binoculars. M109 lies close to the star Phad—Gamma (γ) Ursae Majoris—in the Hig Dipper.

CHARLES MESSIER

M81, A SPIRAL GALAXY (SEE P.304)

M82, AN IRREGULAR GALAXY (SEE P.304)

M97, A PLANETARY NEBULA

M108, A SPIRAL GALAXY

M109, A BARRED SPIRAL GALAXY

I N TR OD U CT I ON

The French comet-hunter Charles Messier (1730–1817) compiled a catalog of 110 nebulous-looking objects in the sky that could be mistaken for comets. Not all of them were discovered by himself— many were spotted by another Frenchman, Pierre Méchain, and yet others had been found years earlier by astronomers such as Edmond Halley. Messier’s first true discovery was M3, a globular star cluster in Canes Venatici. Ironically, Messier is more famous for his catalog of non-comets than he is for the real comets he discovered.

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THE VIEW FROM EARTH

LIGHTS IN THE SKY AS WELL AS STARS, GALAXIES, NEBULAE,

34–37 Radiation 64–67 Celestial cycles Naked-eye astronomy 76–77 Earth’s atmosphere and weather 125 Comets 212–13 Meteors and meteorites 220–21

and solar system objects, other phenomena can cause lights to appear in the night sky. Mainly, these originate in light or particles of matter reaching Earth in various indirect ways from the Sun, but some are generated by Earth-bound processes. Amateur stargazers need to be aware of these sources of nocturnal light to avoid confusion with astronomical phenomena.

AURORAE

AURORA FROM THE SPACE SHUTTLE

This photograph of the aurora australis was taken from the Space Shuttle Discovery during a 1991 mission. A study of the aurora’s features was one of the mission tasks.

ICE HALOES

The aurora borealis (northern lights) and aurora australis (southern lights) appear when charged particles from the Sun, carried to Earth in the solar wind (see pp.106–107), become trapped by Earth’s magnetic field. They are then accelerated into regions above the north and south magnetic poles, where they excite particles of gas in the upper atmosphere, 60–250 miles (100–400 km) AURORA BOREALIS above Earth’s surface. The appearance and location of A colorful display of the northern lights is visible aurorae change in response to the solar wind. They are most often visible at high latitudes, toward Earth’s here over silhouetted trees near Fairbanks, Alaska. magnetic poles, but may be seen at lower latitudes The colors stem from during disturbances in the solar wind, such as after light emission by different mass ejections from the Sun (see pp.106–107). atmospheric gases.

Moon

Atmospheric haloes are caused by ice crystals high in Earth’s atmosphere refracting light. Light either from the Sun or the Moon (that is, reflected sunlight) can cause haloes. The most common halo is a circle of light crystal’s faces with a radius of 22° act as prism around the Moon or Sun. Also present may be splashes of light, called moon dogs or sun dogs (parhelia), arcs, and circles of light that seem to pass through the Sun or Moon. All these phenomena result from the identical angles between the faces of atmospheric ice crystals. Even if the crystals are not all aligned, they tend to deflect light in some directions more strongly than in others.

ice crystal in layer of cirrostratus cloud 22º

22º

OBSERVING A 22º HALO

This halo is formed when ice crystals in the atmosphere refract light from the Moon to the observer on Earth by an angle of 22°. A light ray is refracted through this angle as it passes through two faces of an ice crystal.

halo

parhelic circle moon dog

I N TRO D U CT I ON

HALO AND MOON DOGS

This photograph taken in Arctic Canada shows several refraction phenomena. The patches of light on either side of the Moon, called moon dogs, are caused by horizontal ice crystals in the atmosphere refracting light. The band of light running through the moon dogs is called a parhelic circle. Also visible is a circular 22° halo.

LIGHTS IN THE SKY

75

ZODIACAL LIGHT

SEEING THE ZODIACAL LIGHT

The zodiacal light is most distinct just before dawn in fall, far from any light pollution. It is near the horizon and forms a rough triangle.

A faint glow is sometimes visible in the eastern sky before dawn or occasionally in the west after sunset. Called zodiacal light, it is caused by sunlight scattered off interplanetary dust particles in the plane of the solar system—the ecliptic plane (see p. 64). The mixture of wavelengths in the light is the same as that in the Sun’s spectrum. A related phenomenon is called the gegenschein (German for “counterglow”). It is sometimes perceivable on a dark night, far from any light pollution, as a spot on the celestial sphere directly opposite the Sun’s position in the sky. The dust particles in space responsible for both zodiacal light and gegenschein are thought to be from asteroid collisions and comets and have diameters of about 0.04 in (1 mm).

THE GEGENSCHEIN

This faint, circular glow, 10° across, is most often spotted at midnight, in an area above the southern horizon (for northernhemisphere viewers).

NOCTILUCENT CLOUDS Clouds at extremely high altitude (around 50 miles/ 80 km high) in Earth’s atmosphere can shine at night by reflecting sunlight long after the Sun has set. These “noctilucent” (night-shining) clouds are seen after sunset or before dawn. It is thought that they consist of small, ice-coated particles that SHINING CLOUDS reflect sunlight. Noctilucent Noctilucent clouds clouds are most often seen are silvery-blue and between latitudes between 50° usually appear as and 65° north and south, from interwoven streaks. They are only ever May to August in northern seen against a partly latitudes and November to lit sky background, February in southern latitudes. the clouds occupying They may also form at other a sunlit portion of Earth’s atmosphere. latitudes and times of year.

MOVING LIGHTS AND FLASHES Many phenomena can cause moving lights and flashes across the sky. Rapid streaks of light are likely to be meteors or shooting stars—that is, dust particles entering and burning up in the atmosphere. A bigger, but very rare variant is a fireball—simply a larger meteor burning up. Slower-moving, steady, or flashing lights are more likely to be aircraft, satellites, or orbiting spacecraft. Large light flashes are usually electrical discharges connected with lightning storms. In recent years, meteorologists have named two new types of lightning: “red sprites” and “blue jets.” Both are electrical discharges between the tops of thunderclouds and the ionosphere above. PATH OF THE ISS

These cone-shaped discharges are 30–35 miles (50–60 km) high, 6 miles (10 km) wide at the top, and result from lightning in the atmosphere ionizing nitrogen atoms, causing them to glow blue as they reemit light. In the past, blue jets may have been reported as UFOs.

UFO SIGHTINGS Every year there are reports of unidentified flying objects (UFOs). Most of these can be accounted for by natural phenomena such as brights stars, meteors, aurorae, unusual clouds, or by human-made objects such as satellites and aircraft. After excluding such causes, there are still unexplained cases. It would be unscientific to dismiss the possibility that these UFOs are signs of extraterrestrial visitors without further investigation—just as it would be to accept it before ruling out less exotic explanations. FLYING SAUCER?

This object, suggestive of a flying saucer, is actually a lenticular cloud. Clouds like this are usually formed by vertical air movements around the sides or summits of mountains.

INTRODUCTION

BLUE JETS

As the International Space Station (ISS) orbits Earth, it is visible from the ground because it reflects sunlight. This photograph of the Space Station was taken using a 60-second camera exposure, which indicates how quickly the spacecraft moves across the night sky.

MYTHS AND STORIES

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THE VIEW FROM EARTH

NAKED-EYE ASTRONOMY 62–63 The celestial sphere 64–67 Celestial cycles 68–69 Planetary motion 74–75 Lights in the sky Mapping the sky 348–53 Monthly sky guide 426–501

OPTICAL INSTRUMENTS ARE NOT NECESSARY

to gain a foothold in astronomy—our ancestors did without them for thousands of years. Today’s naked-eye observer, equipped with a little foreknowledge and some basic equipment, can still appreciate the constellations, observe the brightest deep-sky objects, and trace the paths of the Moon and planets in the night sky.

PREPARING TO STARGAZE SEEING AND TWINKLE To get the most from stargazing, Variable “seeing” is caused some preparation is needed. The human eye takes some 20 minutes to by warm air currents rising from the ground at nightfall. adjust to darkness and, as the pupil These telescope images of opens, more detail and fainter objects Jupiter show the range of become visible. Look at a planisphere seeing from poor to fine, or monthly sky chart (see pp.426–501) but seeing also limits the visibility of stars with the to see what is currently in the sky. A naked eye and determines good location is one shielded from the amount of “twinkle.” street lights, and ideally away from their indirect glow. Try to avoid all artificial light—if necessary, use a flashlight with a red filter. Keep a notebook or a prepared report form to record observations, especially if looking for particular phenomena, such as meteors. To see faint stars and deep-sky objects, avoid nights when a bright Moon washes out the sky. Even on a dark, cloudless night, air turbulence can affect the observing quality or “seeing”—the best nights are often those that do not suddenly get colder at sunset. LIGHT POLLUTION

This composite satellite image shows the extent of artificial lighting on Earth. In industrialized regions, it is almost impossible to find truly dark skies. GOOD STREET LIGHTING

In some countries, nonessential street lights are switched off late at night. Elsewhere, shades are installed to project all the light downward, preventing it from leaking into the sky. Such measures can increase the light on the street, save energy, and preserve the night sky for stargazers.

I N TRO D UC TI O N

PLANISPHERE

A planisphere is a useful tool for any amateur astronomer. The user rotates the disks so that the time and date markers on the edge match up correctly, and the window reveals a map of the sky at that moment. A single planisphere is useful only for a limited range of latitudes, so be sure to get one with the correct settings.

THE MOON AND VENUS

Solar system objects such as the Moon and Venus can be spectacular sights even with the unaided eye. This beautiful twilight pairing was photographed in January 2004.

NAKED-EYE ASTRONOMY

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MEASUREMENTS ON THE SKY Distances between objects in the sky are often expressed as degrees of angle. All the way around the horizon measures 360°, while the angle from horizon to zenith (the point directly overhead) is 90°. The Sun and Moon both have an angular diameter of 0.5°, while an outstretched hand can be used to estimate other distances. When studying star charts, bear in mind that one hour of right ascension (RA) along the celestial equator is equivalent to 15° of declination (see p.63), but right ascension circles get tighter toward the celestial poles, so at 60°N an hour’s difference in RA is equivalent to only 7.5° of declination. 1°

3°

4°

20° 6°

10°

FINGER WIDTH

FINGER JOINTS

HAND SPANS

Held out at arm’s length, a typical adult index finger blocks out roughly one degree of the sky—enough to cover the Moon twice over.

The finger joints provide measures for distances of a few degrees. A side-on fingertip is about 3° wide, the second joint 4°, and the third 6°.

The hand (not including the thumb), is about 10° across at arm’s length, while a stretched hand-span covers 20° of sky.

STAR-HOPPING URSA MINOR

The best way to learn the layout of the night sky is to first find a few bright stars and constellations, then work outward into more obscure areas. Two key regions are the Big Dipper (the brightest seven stars in the constellation Ursa Major, close to the north celestial pole) and the area around the brilliant constellation Orion, including the Winter Triangle (see p.436) on the celestial equator. By following lines between certain stars in these constellations, one can find other stars and begin to learn the sky’s overall layout. The Big Dipper is a useful pointer, since two of its stars align with Polaris, the star that marks the north celestial pole. Because the sky seems to revolve around the celestial poles, Polaris is the one fixed point in the northern sky (there is no bright south Pole Star). Other useful keystones are the Summer Triangle (see p.466), comprising the northern stars Vega, Deneb, and Altair, and the Southern Cross (see p.437) and False Cross (see p.443) in the far south.

Polaris

Dubhe

Merak

Alkaid

URSA MAJOR

BOOTES Arcturus

Regulus

LEO VIRGO

Aldebaran

CANIS MINOR

TAURUS

Bellatrix Betelgeuse

Procyon Spica

MONOCEROS ORION

STAR HOPS FROM THE BIG DIPPER ORION’S BELT AND THE WINTER TRIANGLE

The distinctive line of three bright stars forming Orion’s belt points in one direction toward the red giant Aldebaran in Taurus, and in the other toward Sirius, the brightest star in the sky, in Canis Major. Sirius, Betelgeuse (on Orion’s shoulder), and Procyon (in Canis Minor) make up the equilateral Winter Triangle.

Rigel

Sirius

CANIS MAJOR

I N TR OD U CT I ON

A line through Dubhe and Merak along one side of the Big Dipper points straight to Polaris in one direction, and (allowing for the curvature of the sky), toward the bright star Regulus in Leo in the other direction. Following the curve of the Big Dipper’s handle, meanwhile, leads to the bright red star Arcturus in Boötes and eventually to Spica in Virgo.

THE MILKY WAY

The starry band of the Milky Way arches over the snow-covered cliffs of the Creux du Van near Neuchâtel, Switzerland, in a spectacular wide-angle view. The Milky Way is the plane of our Galaxy seen from within—a mass of distant stars interspersed with dusty, concealing nebulae and pink patches of glowing gas where new stars are being born to join the existing billions.

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BINOCULAR ASTRONOMY FOR MOST NEWCOMERS

64–67 Celestial cycles 76–77 Naked-eye astronomy Telescope astronomy 82–85 Mapping the sky 348–53 Monthly sky guide 426–501

to astronomy, the most useful piece of equipment is a pair of binoculars. As well as being easy and comfortable to use, binoculars (unlike telescopes) allow stargazers to see images the right way up. A range of fascinating astronomical objects can be observed through them.

BINOCULAR CHARACTERISTICS Binoculars are like a combination of two low-powered telescopes. The two main designs, called porro-prism and roof-prism, differ in their optics, but either can be useful for astronomy. More important when choosing binoculars are the two main numbers describing their optical qualities; for example, 7x50 or 12x70. The first figure is the magnification. For a beginner, a magnification of 7x or 10x is usually adequate—with a higher magnification, it can be difficult to locate objects in the sky. The second figure is the aperture, or diameter of the objective lenses, measured in millimeters. This number expresses the eyepiece binoculars’ light-gathering power, which is important in seeing faint objects. eyepiece For night-sky viewing, an aperture focusing ring of at least 50 mm (2 in) is preferable. prism eyepiece with focusing ring

prisms

main focus ring

objective lens

objective lens light enters

STANDARD BINOCULARS

These typically have 50mm (2-in) objective lenses and a magnification of 7x or 10x. This pair has a porro-prism design.

light enters

COMPACT BINOCULARS

These are lightweight but their objective lenses are rather small for astronomy. This pair has a roof-prism design.

EXPLORING SPACE

I N TRO D UC TI O N

BINOCULAR FINDS Astronomers make some important discoveries using binoculars. Arizona astronomer Peter Collins uses binoculars to search for the stellar outbursts known as novae (see p.282). To make the method effective, he memorizes thousands of star positions. Comets are also frequently first seen by binocular enthusiasts. Japanese astronomer Hyakutake Yuji spotted Comet Hyakutake (see p.215) in 1996 using a pair of giant (25 x 100mm) binoculars. PETER COLLINS

IDYLLIC SKYGAZING

The modest magnifying power of binoculars is more than enough to reveal many of the sky’s most interesting objects. Wilderness camping is a good way to get away from light pollution.

BINOCULAR ASTRONOMY

USING BINOCULARS

eyepiece handle for adjusting direction of binoculars

tripod

Whatever size of binoculars astronomers choose, it can be difficult to keep them steady. Placing elbows against something solid, such as a wall, or sitting down in a lawn chair, can help stop the binoculars from wobbling. Giant binoculars are too heavy to hold steady in the hands, so should objective lens be supported on a tripod. Another common problem is finding the target object in the field of view, even when the object is visible to the naked eye. One method is to establish the position of the target in relation to an easier-to-locate object, then locate the easier object and finally navigate to GIANT BINOCULARS the target object. Dedicated astronomers Alternatively, work generally prefer binoculars upward from a with objective lenses recognizable feature of 70mm (2.8 in) and magnifications of 15–20x. on the horizon.

KEEPING YOUR BINOCULARS STEADY

Sitting and placing the elbows on the knees can support the weight of binoculars and keep them steady.

HOW TO FOCUS A PAIR OF BINOCULARS

A pair of binoculars is not immediately in perfect focus for every user, since users’ eyesight differs. To fix this, follow the instructions below.

1

The size of the circular area of sky seen through binoculars is called the field of view and is usually expressed as an angle. The field of view is closely related to magnification—the higher the magnification, the smaller the field of view. A typical field of view of a pair of medium-power binoculars (10x) is 6–8°. This offers a good compromise between adequate magnification and a field of view wide enough to see most of a large object such as the Andromeda Galaxy (see pp.312–13). For viewing larger areas still, lower-power binoculars (5–7x), with a field of view of at least 9°, are more suitable. Conversely, for looking at more compact objects, such as Jupiter and its moons, binoculars with higher magnification, and a field of view of 3° or even less, are better to use.

This is how the Andromeda Galaxy (M31, above) appears through medium- to lowmagnification binoculars, with a field of view of about 8°.

IDENTIFY FOCUSING RING

Find which eyepiece can be rotated to focus independently (usually the right). Look through with your eye closed on that side.

BINOCULAR FIELD OF VIEW

M31 VIEWED THROUGH BINOCULARS

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2

FOCUS LEFT EYEPIECE

Rotate the binoculars’ main, central focusing ring, which moves both eyepieces, until the left-eyepiece image comes into sharp focus.

3

CLOSE LEFT EYE, OPEN RIGHT EYE

Now open only the other eye (in this example, the right), and use the eyepiece focusing ring to bring the image into focus.

M31 VIEWED THROUGH A TELESCOPE

Here the central part of the Andromeda Galaxy is shown as you might see it through very-high-magnification binoculars, or a small telescope, with a field of view of about 1.5°.

4

FOCUS AND THEN USE BOTH EYES

Both eyepieces should now be in focus, so now you can open both eyes and start observing.

BINOCULAR OBJECTS

THE PLEIADES

This spectacular star cluster in Taurus is seen here as it appears through high-power binoculars with a field of view of about 3°.

I N TR OD U CT I ON

A striking first object for a novice binocular user is the Orion Nebula (see p.241). Other choices might be the Andromeda Galaxy (above), and the fabulous star clouds and nebulae in the Sagittarius and Scorpius regions of the Milky Way, including the Lagoon Nebula (see p.243). For viewers south of 50°N, an excellent binocular object is the Omega Centauri star cluster (see p.294). To find these, all that is needed is some star charts (see pp.426–501) ORION NEBULA THE MILKY WAY or astronomy software. Also try This appears as a blue-green smudge in Shown here is a dense region of the Milky observing the Moon, Jupiter and Orion, shown here as it appears in mediumWay in Sagittarius, as seen through lowits moons, and the phases of Venus. power binoculars with a field of view of 12°. power binoculars with a field of view of 8°.

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TELESCOPE ASTRONOMY

EXPLORING SPACE

BEFORE THE TELESCOPE

TELESCOPES ARE THE ULTIMATE

optical instruments for astronomy. The simplest spyglass type has changed comparatively little over the centuries, but the most sophisticated amateur instruments now offer the optics and computerized controls once the preserve of professionals.

34–35 Across the spectrum 59 Celestial coordinates Telescopes for beginners 84 Setting up a telescope 86–87

EARLY TELESCOPES

eyepiece lens magnifies image 35 times

In the days before telescopes, astronomers used a variety of instruments for measuring the positions of celestial objects. Tycho Brahe (1546–1601), a Danish nobleman, built his own observatory and equipped it with the finest instruments, which included a huge wall-mounted quadrant. German mathematician Johannes Kepler used Brahe’s measurements of planetary positions when calculating his laws of planetary motion (see p.68).

NEWTON’S TELESCOPE

Isaac Newton developed this first reflecting telescope, and his design is still used. A mirror at one end of the tube “bounces” light toward the eyepiece at the other end.

The invention of the telescope is usually credited to a Dutch optician called Hans Lippershey (1570–1619). In 1608, Lippershey found that a certain combination of optical lenses mounted at either end of a tube magnified an image—the basis of the refracting telescope. News of this device spread across Europe, and a year later the Italian scientist Galileo Galilei (1564–1642) built telescopes that could magnify up to 30 times. His subsequent observations of the Moon, Sun, and stars helped establish the heliocentric (Sun-centered) theory of the Universe proposed by Copernicus (see p.69). In 1668, Isaac Newton developed the reflecting telescope, which used mirrors instead of lenses. There were many advantages: they did not have the optical defects that the refracting instruments had, tubes were shorter, and they could be made with larger GALILEO’S SKETCH OF THE MOON apertures. However, the early The Italian astronomer used his mirrors were made of metal telescopes to observe the craters, and tarnished, so they did mountains, and dark lowland areas not catch on initially. of the Moon.

upper tube covered with vellum

lower tube made of layers of paper and cardboard

light enters tube correcting lens

screw that holds main mirror in position sphere rotates to point telescope tube in different directions

TELESCOPE DESIGNS

convex secondary mirror

finder

A telescope’s function is to collect light from distant objects, bring it to a focus, concave primary and then magnify it. There are two basic ways of doing this, using either a lens or a mirror concave mirror. A lens refracts, or bends, the light passing through it, directing it to a focal point behind it. A curved mirror reflects light rays back onto converging hole in primary mirror paths that come to a focus somewhere in front of it. A combination design called a for light to pass through catadioptric telescope is basically a reflector with a thin lens across the front of the tube. Light rays entering a telescope from astronomical objects are near parallel. eyepiece Once the captured light rays have passed the focus, they begin to diverge again, at which point they are captured by an eyepiece, which returns the rays to parallel directions, magnifying them in the process. Because light rays light enters entering the eyepiece have crossed over as they pass through tube eyepiece the focus, the image is usually inverted, which is not generally regarded as a drawback when viewing focused light astronomical objects. secondary

I N TRO D UC TI O N

REFRACTING TELESCOPE

These telescopes are tubes with a lens, known as the objective, at one end. The lens focuses the incoming light down the tube into an eyepiece at the other end.

piggyback finderscope

mirror

refracted light

objective lens

light enters tube

reflected light

CATADIOPTRIC TELESCOPE

altazimuth fork mount

REFLECTING TELESCOPE focused light 90° eyepiece—a sliding tube allows it to move in and out to focus

equatorial “wedge” mount

With this design, light falls onto a primary mirror at the base of an openended tube. From there it is reflected back up the tube onto a smaller flat mirror, which diverts it into an eyepiece on the side.

convex primary mirror

In this compact reflector design, a convex secondary mirror directs light to the eyepiece through a hole in the primary mirror. By bouncing the light back on itself, the length of the telescope tube is reduced.

TELESCOPE ASTRONOMY

83

TELESCOPE MOUNTS ALTAZIMUTH MOUNT

This type of mount is usually light and compact. However, both axes of the telescope must be moved at the same time to track a celestial object—and the higher the telescope’s magnification, the faster the object will drift out of the field of view. movement in altitude

movement in the right ascension

movement in declination

movement in azimuth

The way a telescope is mounted can greatly affect its performance. The two most common types of mount are the altazimuth and the equatorial. The altazimuth mount allows the instrument to pivot in altitude (up and down) and azimuth (parallel to the horizon). The equatorial mount aligns the telescope’s movement with Earth’s axis of rotation, so that it can follow the lines of right ascension and declination in the sky (see p.63). Altazimuth mountings are simple to set up, but because objects in the sky are constantly changing their altitude and azimuth, tracking objects requires continued adjustment of both. Equatorial mounts are heavier and take longer to set up but, once aligned to a celestial pole, the observer can follow objects across the sky by turning a single axis.

EQUATORIAL MOUNT

These mounts are more awkward to set up, but once that is done the observer can track objects just by turning the polar axis. Some equatorial mounts have electric or batterycontrolled drive motors that allow for handsfree operation.

ALTAZIMUTH VARIATIONS

There are two variants of the altazimuth mount. Fork mounts are often used for catadioptric telescopes. Dobsonians are good for large reflectors with wide fields of view and low magnifications.

FORK MOUNT

APERTURE AND MAGNIFICATION Two major factors affect an image in a telescope eyepiece— aperture and magnification. The aperture is the diameter of the telescope’s primary mirror or objective lens and affects the amount of light it can collect—called its “light grasp.” Doubling the aperture quadruples the light grasp. Magnification is dictated by the specification of the telescope’s eyepiece. The power of the eyepiece is identified by its focal length—the distance at which it focuses parallel rays of light. The shorter the focal length, the greater the magnification. Objective lenses and primary mirrors also have a focal length, and dividing this measurement by that of the eyepiece gives the combined magnification. An eyepiece can be changed to alter the magnification to suit the observed object.

66mm APERTURE

120mm APERTURE

APERTURE

50mm APERTURE

The shorter the focal length of an eyepiece, the higher its magnifying power but also the smaller its field of view. This can be seen clearly in these two photographs of the Moon. The image far left was taken through a 9mm eyepiece; the second image was taken through a 25mm eyepiece. 25mm EYEPIECE

FOCAL LENGTH AND FOCAL RATIO

objective lens

focal length

VARIATIONS IN FOCAL RATIO Telescopes with a large focal ratio, such as f/10, above, produce larger images but have smaller fields of view than telescopes with lower focal ratios.

After the aperture, the next most important specification of a telescope is its focal length. This is the distance from its primary lens or mirror to the point where the rays of light meet—the focal point. A telescope with a long focal length produces a large but faint image at its focal point, whereas one with a shorter focal length gives a smaller but brighter image. It is easier to make mirrors with short focal lengths than it is lenses, so reflecting telescopes can have shorter tubes for a given aperture. Dividing the focal length of the primary mirror or lens (usually given in millimeters), by the telescope’s aperture (also in millimeters) will give its focal ratio, called its “f ”number. This ratio can influence the type of celestial object observed. Telescopes with a low focal ratio, around f/5, are best for imaging diffuse objects, such as nebulae or galaxies; those with a focal ratio above f/9 are useful for studying brighter objects, such as the Moon or the planets.

I NT RO D UC TI O N

f/5 FOCAL RATIO

These are photographs of the open cluster M35. The image far left was taken through a telescope with a 2 in (50mm) objective lens; the second image, left, was taken through a 4 in (100mm) lens. The larger lens has a light grasp four times greater than the smaller one, so the fainter stars can be seen more clearly.

MAGNIFICATION

9mm EYEPIECE

aperture

100mm APERTURE

OBJECTIVE SIZES The most important specification of a telescope is the diameter of its objective lens. This affects how much light can enter the tube.

f/10 FOCAL RATIO

DOBSONIAN MOUNT

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TELESCOPES FOR BEGINNERS

finderscope

Choosing a telescope to suit your needs and experience can make a difference to your viewing. Many people start with a basic telescope, possibly on an altazimuth mount (see p.83), such as a Dobsonian, then learn how to find objects in the sky. Others opt for a more advanced computerized go-to telescope that will find celestial objects at the press of a button. These are invaluable for locating hard-to-find objects, and most include a sky-tour that will show the highlights visible at any given time and provide background information. Once an object has been located, the instrument will track it automatically for as long as required. Go-to telescopes may have altazimuth or equatorial mounts— the former are fine for visual observing, the latter are essential for longexposure photography. Consider, too, whether you need your telescope to be portable. In general, the larger the telescope’s aperture the better, but there is no point in having an instrument that you rarely use because it is too big and cumbersome to set up. Most instruments perform well on all subjects. Refracting telescopes tend to be better suited to use in towns, where light pollution can be a problem, while country sites favor reflecting telescopes.

star diagonal rotates image through 90° to give a more comfortable observing position

German-type equatorial mount with motor drive for tracking moving objects

FINDERS

A telescope’s field of view is small, even if using the lowest magnification eyepiece. It is typically only one degree, which is just twice the size of the full Moon in the sky. Simply aiming the telescope can be hit-and-miss. A finder, which is a small refracting telescope that sits on the side of the main instrument, helps you aim your telescope with much greater precision. Almost all telescopes require a finder to help locate objects, or for go-to telescopes to set them up in the first place. There are two main types: finderscopes and red dot finders. Optical finderscopes are useful where there is light pollution because they can show stars not otherwise visible, although red dot finders can be easier to use. Both are mounted on the telescope tube in such a way that they can be adjusted to match the aiming point of the main instrument (see below right). Align the finder by looking at a distant fixed object, ideally in daylight. Never use the Sun, which could blind you. Switch the finder off after using it to avoid a dead battery later.

adjustments to mount enable it to be used at any latitude

GO-TO TELESCOPE

This equatorially mounted Schmidt– Cassegrain telescope is a typical computerized instrument. It has a handset for entering the details of target objects and a hand-held controller for adjustments in right ascension and declination. It can also interface with a computer.

handset for choosing target objects and adjusting telescope position in right ascension and declination

FINDERSCOPE A finderscope magnifies the night sky and gives a field of view of around 5–8°. A crosshair helps center the target in the finderscope. The image through the finderscope is inverted, which can, at first, make finding objects frustrating. Most entrylevel telescopes come with a basic finder, but it may be worth upgrading as you progress. FINDERSCOPE VIEW

I N TRO D UC TI O N

eyepiece

mounting bracket

USING A FINDER

RED DOT FINDER A red dot finder indicates where the telescope is pointing by projecting a small red dot onto a piece of transparent glass or plastic. The wider sky remains visible, making it intuitive to use. The brightness of the dot can sometimes be adjusted with a built-in sight dimmer switch. RED DOT FINDER VIEW

alignment adjustment wheel

mounting bracket

FIND AN OBJECT To align any finder, first select a distant and fixed object in the main instrument using its lowest magnification eyepiece, then center it within the field of view. Clamp the telescope’s position.

1

2

ALIGN THE FINDER Using the adjusters on the finder, bring the same object into the center of the finder’s crosshairs or red dot (see far left). You may need to repeat this each time the finder is removed and replaced.

TELESCOPE ASTRONOMY

85

EYEPIECES Most telescopes are supplied with one or two eyepieces: one that gives a basic low magnification, or power; and the other providing a higher power. To increase magnification further you need additional eyepieces, but there is also a limit to the power that any telescope can tolerate, often given as twice its aperture in millimeters. For example, the limit of a 130mm telescope is 260. As the power is increased, the field of view usually decreases, the image dims, any atmospheric turbulence (called the “seeing”) is emphasized, and it becomes harder to keep objects within the field of view. One way to increase the power of a set of eyepieces is to place a Barlow lens between the telescope and the eyepiece. This lens typically doubles the power of each eyepiece, giving you a wider range of magnifications from a small set of eyepieces.

TELESCOPE VIEW

NAKED-EYE VIEW

STAR DIAGONAL This is a device often used with refractor and catadioptric telescopes to improve observing position, but it also reverses the image.

EYEPIECES

Telescope eyepieces are available in a range of focal lengths, with the highest figure giving the lowest magnification. The optical design varies, some combining a very wide apparent field of view with a high power. 40mm

25mm

9mm

2X BARLOW LENS

ANTI-LIGHTPOLLUTION FILTER

FILTERING OUT LIGHT POLLUTION

Street lamps emit yellow light with a narrow range of wavelengths, making the sky glow orange (above). A light-pollution filter can cut it out while leaving the light from distant stars unaffected (right).

SOLAR TELESCOPES The Sun is a fascinating object to observe with constantly changing features, but it is also the most dangerous, because it is so bright that even a momentary view through a telescope can blind the viewer. Specialized filters are available that reduce the brightness of the incoming light, which must be done because light enters the tube rather than at the eyepiece, where the light is focused. Only filters specifically designed for the purpose should be used because other dense material may transmit harmful infrared light. Many of the Sun’s most fascinating features are visible only in the deep red hydrogenalpha wavelength emitted by hydrogen gas. Filters that only transmit this light are very expensive, so even a basic solar telescopes can cost as much as a digital SLR camera. Specialized instruments called solar telescopes are also available. These reveal fascinating detail on the surface of the Sun, as well as the prominences around its edge. THE SUN’S SURFACE

SOLAR TELESCOPE

This solar telescope view of the Sun shows granulation and sunspots, bright areas called faculae, prominences at the Sun’s edge, or limb, and strandlike filaments seen against the Sun’s bright surface.

Amateur astronomers gather in dark-sky areas at what are often called star parties. Only red lights are allowed, because they interfere less with night vision than lights of any other colour.

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STAR PARTY

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SETTING UP A TELESCOPE 62–63 Celestial coordinates 82–83 Telescope astronomy Mapping the sky 348–53 Ursa Major 360–61

THE SKY IS CLEAR, the

forecast is good, and your first night of observing lies ahead. However, there is a steep learning curve to negotiate before you can start to see the sky’s wonders. Even relatively simple telescopes can magnify objects many dozens of times, so locating apparently obvious bright objects can be surprisingly difficult. The secret to successful observations is to get your bearings before you begin. It may seem obvious, but make sure you know where north and south are—even go-to telescopes may need you to point them in the right direction initially.

MOUNTING A TELESCOPE

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LEVEL TRIPOD Set up your tripod on solid, level ground. Use a spirit level to check that the top plate of the tripod is horizontal and adjust the tripod legs as necessary.

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After buying a telescope, it is important to take time to set up its optics, tripod, and mount properly. Careful setup will leave you with a well-aligned and balanced telescope that is a joy to use, and that will require minimum tweaking during those precious observing hours. Each telescope is different, so be sure to read the instructions provided before you start or, better still, ask an experienced astronomer to take you through the basics. Below is a brief and general guide to the main points of setting up a typical amateur telescope—a reflector on a motorized equatorial mount.You will probably want to leave your telescope partly set up between observing sessions, so some of the steps will only need to be carried out the first time you use it.

ADJUST LEGS Avoid extending the sections of the tripod legs to their full extent, because this makes the platform less stable and gives you no latitude for fine adjustment of height later. Double-check that the locks on the legs are secure.

PLACE MOUNT Gently position the mount onto the tripod, ensuring that the protrusion on the mount slots into the hole on the tripod.

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SECURE MOUNT Tighten the mounting screw from beneath the tripod head, making sure it is completely secure.

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ATTACH MOTOR DRIVE Attach the motor drive to the mount and ensure that the gears of the motor are correctly engaged with those on the mount.

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ALIGN NORTH If using an equatorial mount, check that the right ascension axis (the long part of the central “T” of the mount) is pointing roughly toward the north (or south) celestial pole, depending your hemisphere.

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7

ADD COUNTERWEIGHTS Slot the counterweights onto the counterweight shaft and use the nut to secure the weights in position. There is usually a safety screw at the end of the shaft that stops the counterweights from sliding off should the main nut fail. Be sure to replace this safety screw after positioning the weights.

MOUNT THE TELESCOPE Once the mount is on the tripod, you can mount the telescope tube. Place the tube inside the pair of circular mounting rings (called cradles) and clamp them tight around the tube using the screws.

ADD FINE ADJUSTMENT CABLES Screw in the fine adjustment cables— these will allow you to make small changes to the right ascension and declination when observing.

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ADD THE MOTOR UNIT Plug the drive controller into the motor unit, but do not connect it to the power supply.

SETTING UP A TELESCOPE

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FIT THE FINDER AND EYEPIECE Attach the lowest-magnification eyepiece (the one with the longest focal length) and fit the finder. Align your finder with the main instrument —ideally do this during the daytime (see p.84).

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BALANCE DECLINATION (DEC) Position the mount so that the telescope is out to one side and loosen the declination axis clamp. Support the telescope. Slacken the cradle screws enough to be able to slide the tube to and fro until it is balanced, then tighten them.

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BALANCE RIGHT ASCENSION (RA) Supporting the telescope with one hand, loosen the clamp on the RA axis and disengage the motor drive if necessary. Adjust the position of the counterweight on its shaft until it balances the telescope and the axis turns freely.

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POWER UP Connect the motor to the power supply, and then finetune the polar alignment (see below).

ALIGNING TO THE POLE To set up an equatorial mount, you need to direct the RA axis, or polar axis, at the celestial pole. How you do this depends on your instrument. With simpler instruments, use the latitude scale usually provided on the mount (see below). On advanced instruments, sight the known position of the pole in the sky (see right).The pole is due south or north, depending on your hemisphere, and at the same angle to the horizon as your geographical latitude. For most observing, approximate alignment by eye is good enough to allow objects to be tracked for many minutes.

ALIGNING ADVANCED MOUNTS

Cas s i op

ei a

Looking through a Northern Hemisphere polarscope (left), you will see a reticule engraved with several constellations and a circle offset from a crosshair (below). Turn the reticule until the constellations match their positions in the sky, then adjust the whole mount so that Polaris sits in the small circle.

The

ALIGNING SIMPLE MOUNTS Point the polar axis to the north or south depending on hemisphere. Turn the adjuster until the angle on the scale is at your latitude.

Bi

g

Di

ppe

r

SETTING UP GO-TO TELESCOPES

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MOUNT THE TELESCOPE Use a spirit level to check that the tripod is level. Gently lower the mount and telescope onto the tripod head and secure it in position.

PREPARE THE TELESCOPE Connect the mount to the power pack and switch on the mount. Remove the lens cover.

SET POSITION Move the telescope into its start position if required. For a fork-mounted instrument (shown), this may just mean aligning two arrows; but an equatorial mount will need polar alignment (see above right).

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ENTER START DATA Enter the date, time, and location into the handset as prompted. On some go-to telescopes, you select your location from a menu.

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ALIGN THE TELESCOPE Alignment methods vary between models, but typically, the instrument will choose a bright star and move automatically to where it thinks the star should be. Alternatively, you can choose the first star from the menu.

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ADJUST ALIGNMENT The first star should be visible in the finder. Center this star using the directional buttons on the handset, then look through the eyepiece to refine its position. Repeat steps 5 and 6 to align two or three more stars as required, then alignment is complete.

SET THE DESTINATION The go-to telescope is now ready. To explore the sky, find the name of the object you want to observe (such as Jupiter) in the handset’s menus and press “go-to” or “enter.” The telescope will then move to center your chosen object in the eyepiece.

I N TR OD U CT I ON

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Every go-to telescope has a virtual map of the sky in its memory so that once it knows its precise location, the time, and the direction it is pointing to, it can find any celestial object. Encoders on each axis count the number of motor rotations the instrument makes as it “drives” from one object to another. With some simple go-to telescopes (see below), time and location must be input before the instrument is set in its start position, such as leveled and pointed north or south. It then has to be pointed at three bright alignment stars. Depending on the model, these may be chosen from the telescope’s catalog or simply any three bright stars or planets. Advanced models are fitted with a GPS (Global Positioning System) receiver that automatically sets the time and location, as well as cameras that locate known bright stars. Whichever type of go-to telescope you have, it is essential that you align the finder with your main instrument before you begin (see p.84).

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THE VIEW FROM EARTH

ASTROPHOTOGRAPHY 82 Telescope designs 83 Telescope mounts 84 Telescopes for beginners Mapping the sky 348–53 Monthly sky guide 426–501

WITH MODERN TECHNOLOGY, amateur

astronomers can now take images that would previously have been possible only from professional observatories. Even compact digital cameras can photograph bright objects, such as the Moon, through a telescope and can capture sky views, such as twilight scenes and constellations.

BASIC ASTROPHOTOGRAPHY Almost any camera can be used to take pictures of the night sky, although without a telescope it is limited to recording little more than naked-eye views of the stars, the Moon, bright planets, meteor trails, constellations, and aurorae. The main requirement for basic astrophotography is that the camera can keep the shutter open for long periods—at least several seconds. With long exposures, it is essential to keep the camera steady by mounting it on a tripod. Using a cable release, remote release, or timer to trigger the shutter will also help to avoid shake and blurring of the image.

FIXED-CAMERA SHOTS

General sky photography requires exposure times of many seconds with the camera at its most sensitive setting and focused on infinity. Mount the camera on a tripod to hold it steady during the exposure.

METEORS

Individual meteors cannot be predicted and so the only way to photograph them is to use long exposures in the hope that one will appear by chance. The field of view of an ordinary camera is ideal, and the exposure time should be as long as possible without the image being saturated by background light. Bright meteors will record as streaks against the background of star trails.

DIGISCOPING AND PIGGYBACKING

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Compact cameras can be used to take images directly through a telescope, a technique known as digiscoping. At its simplest, the camera can be mounted on a tripod and pointed down the telescope eyepiece. Alternatively, an adapter can be used to fix the camera to the eyepiece. Attaching the camera on top of a motordriven equatorially mounted telescope—known as piggybacking— allows long-exposure views of the sky and even deep-sky objects without producing trails on the image. The image recorded is the one captured by the camera, not that seen through the telescope.

STAR TRAILS

During a fixed-camera exposure of more than a few seconds, the stars will trail across the image as they appear to move due to Earth’s rotation —in this case, around the celestial pole. In light-polluted areas, take numerous shorter exposures and stack them using image-processing software to avoid an overexposed sky background.

DIGISCOPING IMAGE OF THE MOON

Excellent images of the Moon can be obtained by digiscoping with even simple cameras. As the Moon is so bright, the exposure time for a Moon picture is similar to that for an ordinary daytime shot.

piggyback-mounted camera with telephoto lens

catadioptric telescope

remote release

DIGISCOPING SET-UP

PIGGYBACK SET-UP

An adapter enables the camera to be aligned with the telescope eyepiece. Set the camera to manual exposure and use the self-timer to avoid shaking the camera. Experiment with different exposure times for the best results.

Many motor-driven telescopes have a threaded bolt for piggybacking a camera. If a telephoto lens is mounted on the camera and a long exposure is used, clear images of even deep-sky objects can be obtained.

ASTROPHOTOGRAPHY

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PRIME-FOCUS ASTROPHOTOGRAPHY

catadioptric telescope

A telescope is, in effect, a very long telephoto lens, and adapters are available to attach virtually any single-lens reflex (SLR) camera to a telescope, thereby enabling the image produced by the telescope to be recorded. However, the maximum exposure time is often limited by the accuracy of the telescope’s drive, which may not be precise enough to prevent star trailing. This problem can be overcome by using many short “sub-exposures” and adding them together with image-processing software to give the equivalent of a single long exposure. The telescope also needs to be kept steady, so a remote release should be used or, if possible, the camera should be operated remotely from a computer.

remote release

PRIME-FOCUS IMAGE OF THE DUMBBELL NEBULA camera adapter

Prime-focus imaging is ideal for galaxies and small objects such as planetary nebulae— the Dumbbell Nebula shown here, for example. Exposure times of many minutes are needed for such images. To overcome any drive errors, the technique of sub-exposures (see above) can be used or a device called an autoguider can be fitted to the telescope to monitor the drive rate and make small corrections automatically.

equatorial mount with motor drive

SLR camera

PRIME FOCUS SET-UP

This technique uses an adapter to place the camera in the eyepiece position, with or without the eyepiece present. A motor-driven equatorial mount is needed to keep the target object in the field of view.

WEBCAMS AND CCD IMAGING Digital SLR cameras can produce good astronomical images but many advanced astrophotographers use either webcam-based cameras for planetary imaging or CCD cameras for imaging faint objects that require very long exposures. Planetary imaging is often badly affected by atmospheric turbulence, which typically blurs the view so that it is sharp for only fractions of a second. Webcam-type cameras produce a video stream, taking thousands of images a minute. WEBCAM SET-UP These images can then be processed A webcam can be used on by dedicated software that selects and even small telescopes to stacks together the best images. For image the planets. The webcam slots into the imaging faint objects that require telescope in place of the exposures of several hours, cooled eyepiece and connects to a CCD cameras produce less electronic computer with a cable. The noise—and therefore better images— webcam is then operated than digital SLRs. from the computer.

CCD camera

CCD IMAGING SET-UP

Like a webcam, a CCD camera replaces the telescope eyepiece and is connected to a computer. To quickly establish the focus when using a CCD camera, it helps first to focus using a telescope eyepiece with the same focus position as the camera.

IMAGE PROCESSING Many images take far longer to process than the original observing time at the telescope, but there are various image-processing programs that can help. For example, software is available for automatically overlaying in register and stacking multiple exposures of the same object. Some cameras (notably CCD cameras) produce monochromatic images but can be used with color filters to produce a series of images that can be combined using stacking software to give a full-color final image. Software can also be used to enhance images by sharpening details, correcting the color balance, altering the brightness, and increasing the contrast. In addition, image-processing software can be used to change individual colors, a technique that is often utilized by professional astronomers to highlight specific features. COLOR CONTROL

This screenshot shows an image of Saturn in Photoshop, software that can be used to enhance or alter an image’s features, such as its color. In this image, the brightest ring is composed of ice and needs to be altered to white to show a realistic view of the planet.

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DIGITAL STACKING The image (left) of NGC 1977, the Ghost Nebula in Orion, was made through an amateur 12.5 in (300 mm) telescope and is the result of combining four individual 90-minute exposures using dedicated imagestacking software.

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ASTRONOMICAL OBSERVATORIES 23 The observable universe 36–37 Across the spectrum 57 Looking for life 82 Telescope designs Observing from space 94–95

SINCE ABOUT THE

early 20th century, many new astronomical observatories have been built, housing ever-larger telescopes. Many of these instruments are visible-light telescopes, but with continuing technological advances, telescopes for studying other parts of the electromagnetic spectrum have also been built, such as radio telescopes and gamma-ray telescopes.

OBSERVATORY TELESCOPES

PALOMAR OBSERVATORY

Most observatory telescopes are sited away from the air and light pollution of urban areas and at high altitude to minimize atmospheric distortion. The size of a telescope is also important: the larger a telescope’s aperture, the greater its light-gathering power. Objective lenses for refractors cannot be made more than about 40 in (1 m) across—the size of the Yerkes HALE REFLECTOR refractor (below left)—but single-piece mirrors can be made up to Opened in 1948, the about 200 in (5 m) across—the size of the Hale reflector (right). Using 200 in (5 m) Hale reflector at Palomar Observatory segmented mirrors, reflectors can be made even larger. For example, the was for many years the Gran Telescopio Canarias has a segmented mirror 34 ft (10.4 m) across.

Like all large, modern observatories, the Palomar in California, USA, was built at high altitude (1,712 m/5,617 ft) for optimum viewing conditions.

world’s largest telescope, and it is still in operation today. The image on the right shows the instrument inside its dome on its massive equatorial mount.

YERKES REFRACTOR

I N TRO D UC TI O N

Refracting telescopes reached their pinnacle with the 40 in (1 m) instrument at Yerkes Observatory, Wisconsin, USA, shown on the left. Opened in 1897, it remains the largest refractor ever built.

PARANAL OBSERVATORY

Situated at an altitude of 8,645 ft (2,635 m) on Cerro Paranal in northern Chile, the Very Large Telescope (VLT) is one of the largest modern telescope arrays, consisting of four 26.9 ft (8.2 m) reflectors. The telescopes operate at visible light and infrared wavelengths and can be used either independently or in combination for greater resolution.

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NEW OPTICAL TECHNOLOGY In their quest for greater light grasp and sharper images, optical astronomers have utilized innovative new technology, such as mirrors made up of many separate segments. Segmented mirrors can be made much thinner, and hence lighter, than a single large mirror. The segments are usually hexagonal in shape, and each one can be individually controlled to maintain sharp focus as the telescope is moved. Mirrors larger than 26.2 ft (8 m) in diameter are now made in this way, and segmented mirrors up to 128 ft (39 m) wide are planned. Another advance has come from adaptive optics, a technique that removes the blurring effects of the atmosphere and can produce images almost as sharp as those from telescopes in space. This is done by measuring atmospheric distortion using an artificial guide star created by firing a laser beam along the telescope’s line of sight. Using these measurements, a flexible secondary mirror (which collects the light from the main mirror) is then deformed to compensate for the distortion. SEGMENTED TELESCOPE MIRROR

The Gran Telescopio Canarias, also known as the GranTeCan or GTC, has a mirror 34 ft (10.4 m) in diameter—the world’s largest. Opened in 2009, it is located at the Roque de los Muchachos on La Palma in the Canary Islands. Its mirror (shown left) is composed of 36 hexagonal segments, each of which is 75 in (1.9 m) wide.

THE LARGE BINOCULAR TELESCOPE

A novel design for increasing light grasp and resolving power is the Large Binocular Telescope at Mount Graham, Arizona, USA. It consists of two mirrors, each 27.6 ft (8.4 m) in diameter, side by side on the same mount. Together, the two mirrors collect as much light as a single mirror 38.7 ft (11.8 m) across.

BEYOND VISIBLE LIGHT

A powerful beam of orange laser light shoots skyward from one of the components of the Very Large Telescope (VLT) in Chile, creating an artificial guide star 55 miles (90 km) high. The guide star is part of the VLT’s adaptive optics system, which helps correct for image distortion caused by atmospheric disturbances. EFFECT OF ADAPTIVE OPTICS

These images of the center of the Galaxy through the Keck II telescope in Hawaii show the effect of adaptive optics. The image on the left was taken without adaptive optics; the much sharper image on the right was taken with the adaptive optics system in operation.

GREEN BANK RADIO TELESCOPE

The world’s largest fully steerable radio telescope, at the National Radio Astronomy Observatory at Green Bank, West Virginia, USA, has an elliptical dish 360 x 328 ft (110 x 100 m) across. The dish consists of over 2,000 panels, each of which can be adjusted separately to maintain the shape of the dish as the telescope moves. The secondary reflector (which reflects radio waves from the main dish to the radio detector) is on an arm to avoid obstructing the main dish.

I NT RO D UC TI O N

Many celestial objects emit energy outside the visible light spectrum (see pp.36–37), so optical telescopes alone cannot give a complete view. The first non-visible-light telescope was a radio telescope, built in 1937. Radio waves have much longer wavelengths than visible light, so radio telescopes have to be larger to achieve the same resolution. To overcome this restriction, radio dish arrays have been built so that observations from individual dishes can be combined. An example is the Karl G. Jansky Very Large Array near Socorro, New Mexico, USA, which consists of 27 dishes, each 82 ft (25 m) wide, arranged along three arms 13 miles (21 km) long. The largest single radio dish is 1,000 ft (305 m) in diameter at Arecibo, Puerto Rico. Most non-visible-light wavelengths other than radio are blocked by the atmosphere. However, some infrared reaches mountaintops and can be detected by certain telescopes, such as the United Kingdom Infrared Telescope in Hawaii. It is also possible to detect cosmic gamma rays at the Earth’s surface. The MAGIC telescope at La Palma in the Canary Islands achieves this by detecting the faint light emitted by particle showers generated by gamma rays.

LASER GUIDE STAR

MILLIMETER ARRAY

Moonlight illuminates the antennae of the Atacama Large Millimeter Array (ALMA) on the Chajnantor Plateau in Chile. Each of the dishes is 39 ft (12 m) in diameter and observes the sky at millimeter and submillimeter wavelengths, between the infrared and radio parts of the spectrum, detecting objects in nearby star-forming regions to galaxies in the distant universe.

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OBSERVING FROM SPACE 34 Electromagnetic radiation 36–37 Across the spectrum 90–91 Astronomical observatories Studying the Sun from space 105

MANY OF THE GREATEST

discoveries and most spectacular images of the universe have come from observatories in space. Above Earth’s atmosphere, telescopes can see the sky far more clearly than those on the ground, and they can detect wavelengths that the atmosphere blocks.

VISIBLE AND ULTRAVIOLET LIGHT Among the first successful space telescopes were those designed to detect ultraviolet light, notably NASA’s Orbiting Astronomical Observatory series, launched between 1966 and 1972, and the International Ultraviolet Explorer, which was launched in 1978 and carried a 1.5 ft (0.45 m) telescope. Probably the most famous space telescope is the Hubble Space Telescope (HST), which was launched in 1990 and is still in operation. With a 7.9 ft (2.4 m) telescope designed primarily to detect visible and ultraviolet light, the HST has, among other successes, helped determine the age of the universe and produced evidence for the existence of dark energy.Visible- and ultraviolet-light space telescopes have also advanced more traditional realms of astronomy. For example, Hipparcos (launched in 1989) has catalogued the positions, distances, and motions of over 100,000 stars, and its work is to be extended by a successor, Gaia.

THE HUBBLE SPACE TELESCOPE

The entire Hubble craft is 43.5 ft (13.2 m) long and 14 ft (4.2 m) wide. The telescope is a reflector with a mirror 7.9 ft (2.4 m) in diameter. It operates primarily in visible light and ultraviolet, although its coverage also extends into the near-infrared.

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HUBBLE DEEP-SKY VIEW

GAIA ASTRONOMETRY SATELLITE

Due for launch in 2013, Gaia is scheduled to spend five years measuring the positions, distances, and motions of a billion stars to create a three-dimensional map of our galaxy and its surroundings.

This image from the Hubble Space Telescope shows a collection of galaxies of different sizes and at various stages of development stretching away for billions of lightyears. The light from such distant objects is so faint that very long exposure times are necessary— nearly 40 hours for this image. Also visible are stars in our galaxy; the bright object above right of center is one of these.

LAUNCH OF THE HUBBLE SPACE TELESCOPE

Launched in April 1990 from the Kennedy Space Center, Florida, USA, on board the Space Shuttle Discovery, the Hubble Space Telescope orbits about 380 miles (600 km) above Earth. Initially intended to operate for 10 years, Hubble is still in operation thanks to five servicing missions by astronauts.

OBSERVING FROM SPACE

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INFRARED AND MICROWAVE Some infrared and microwave radiation penetrates Earth’s atmosphere but to detect the full range requires observing from space. Prominent targets for observation are cool stars and active galaxies, which emit much of their radiation in the infrared. Infrared telescopes also make it possible to see through interstellar dust clouds into regions obscured from optical view, such as the interiors of nebulae and the center of our galaxy. The largest infrared space telescope in operation is the Herschel Space Observatory (launched in 2009), which has a mirror 11.5 ft (3.5 m) across. Microwave space telescopes are designed primarily to detect and map the cosmic microwave background radiation, in order to investigate the structure and origin of the universe. The first dedicated microwave space telescopes were the PLANCK IMAGE OF STAR-FORMATION Cosmic Background Explorer, launched REGION IN PERSEUS in 1989, and the Wilkinson Microwave This false-color image of a low-activity Anisotropy Probe (see p.34), launched in star-formation region was produced by 2001. The most recent is the Planck space combining data from Planck at three different microwave wavelengths. telescope, which was launched in 2009.

PLANCK SPACE TELESCOPE

Shown here being tested before launch, the Planck space telescope is designed to study the cosmic microwave background radiation. It has a 4.9 ft (1.5 m) main mirror and is more sensitive and has greater resolution than its predecessor, the Wilkinson Microwave Anisotropy Probe.

X-RAYS AND GAMMA RAYS

XMM-NEWTON X-RAY SPACE TELESCOPE

The shortest wavelengths of all, X-rays and gamma rays, are produced by some of the most violent events in the universe, such as supernova explosions. However, like infrared and microwave radiation, X-rays and gamma rays are best studied from space. Major X-ray space observatories include the Chandra X-ray Observatory (see p.35) and XMM-Newton, both launched in 1999, and the Suzaku observatory, launched in 2005. Notable gamma-ray space telescopes include the Compton Gamma Ray Observatory (see p.35), launched in 1991, and the Fermi Gamma-ray X-RAY EMITTING CLOUD Space Telescope, which was launched in 2008 and This XMM-Newton image shows an X-ray-emitting carries an instrument designed to study gamma-ray cloud of ultra-hot gas, at bursts, which are thought to be emitted by the temperatures up to about merger of black holes and neutron stars and also by 90 million °F (50 million °C), the collapse of massive stars to form black holes. around a giant elliptical galaxy.

Launched in 1999, the XMM-Newton contains three X-ray telescopes for the imaging and spectroscopy of X-ray sources. The entire satellite is 33 ft (10 m) long and is in a highly elliptical orbit that, at its most distant, takes the satellite more than 60,000 miles (100,000 km) from Earth.

EXPLORING SPACE

LAGRANGIAN POINTS L4

Earth Moon L1

Sun

FIXED ORBITS

This diagram shows the five Lagrangian points in the Earth–Moon–Sun system. Satellites at these points orbit the Sun, not Earth, and include SOHO (see p.105) at L1, and Herschel and Planck at L2.

L5

L2

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Satellites can be placed in various orbits around the Earth or other celestial objects. Some satellites are placed at specific points called Lagrangian points. These are locations where the orbital motion of a small object (such as a satellite) and the gravitational forces acting on it from larger bodies (such as nearby planets and stars) balance each other. As a L3 result, the small object remains in a fixed position relative to the larger bodies. There are five such points in the Earth–Moon–Sun system.

GUIDE TO THE UNIVERSE

TH E S O LA R S Y S TE M

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“How vast those Orbs must be, and how inconsiderable this Earth, the Theatre upon which all our mighty Designs, all our Navigations, and all our Wars are transacted, is when compared to them.” Christiaan Huygens

THE SOLAR SYSTEM IS the region of space that falls within the gravitational influence of the Sun, an ordinary yellow star that has shone steadily for almost 5 billion years. After the Sun itself, the most significant objects in the solar system are the planets—a group of assorted rocky, gaseous, and icy worlds that follow independent, roughly circular orbits around their central star. Most of the planets are orbited in turn by moons, while a huge number of smaller lumps of rock and ice also follow their own courses around the Sun—though largely confined in a few relatively crowded zones. Myriad tiny particles flow around all these larger bodies— ranging from fragments of atoms blown out by the Sun to motes of dust and ice left in the wake of comets. Our local corner of the universe has been studied intensively from the time of the first stargazers to the modern era of space probes, yet it is still a source of wonder and surprise. SOLAR FLARE

On the broiling surface of the Sun, a cataclysmic release of magnetic energy triggers a solar flare—a violent outburst of radiation and high-energy particles that will reach Earth within hours.

THE SOLAR SYSTEM

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THE HISTORY OF THE SOLAR SYSTEM

THE HISTORY OF THE SOLAR SYSTEM THE SOLAR SYSTEM IS THOUGHT

to have begun forming about 4.6 billion years 24–27 Celestial objects ago from a gigantic cloud of gas and 34–37 Radiation dust, called the solar nebula. This cloud 38–39 Gravity, motion, and orbits contained several times the mass of the 68–69 Planetary motion present-day Sun. Over millions of years, it collapsed into a flat, spinning disk, which had a dense, hot central region. The central part of the disk eventually became the Sun, while the planets and everything else in the solar system formed from a portion of the remaining material. 22–23 The scale of the universe

1 SOLAR NEBULA FORMS

The solar nebula started as a huge cloud of cold gas and dust, many times larger than our present solar system. Its initial temperature would have been about –382°F (–230°C). From the start, the solar nebula was probably spinning very slowly.

SIX STEPS TO FORM A SOLAR SYSTEM

Shown here is an outline of the nebular hypothesis—the most widely accepted theory for how the solar system formed. It provides a plausible explanation for many of the basic facts about the solar system. For example, it explains why the orbits of most of the planets lie roughly in the same plane and why the planets all orbit in the same direction.

THE FORMATION OF THE SOLAR SYSTEM No one knows for certain what caused the great cloud of gas and dust, the solar nebula from which the solar system formed, to start collapsing. What is certain is that gravity somehow overcame the forces associated with gas pressure that would otherwise have kept it expanded. As it collapsed, the cloud flattened into a pancake-shaped disk with a bulge at its center. Just as an ice skater spins faster as she pulls in her arms, the disk began to rotate faster and faster as it contracted. The central region also became hotter and denser. In the parts of the disk closest to this hot central region, only rocky particles and metals could remain in solid form. Other materials were vaporized. In due course, these rocky and metallic particles gradually came together to form planetesimals (small bodies of rock, up to several miles in diameter) and eventually the inner rocky planets—Mercury, Venus, Earth, and Mars. In the cooler outer regions of the disk, a similar process occurred, but the solid particles that came together to form planetesimals contained large amounts of various ices, such as water, ammonia, and methane ices, as well as rock. These materials were destined eventually to form the cores of the gas-giant planets— Jupiter, Saturn, Uranus, and Neptune.

PIERRE-SIMON DE LAPLACE Pierre Laplace (1749–1827) was a French mathematician who developed the nebular hypothesis—the idea, originally proposed by the German philosopher Immanuel Kant, that the solar system originated from the contraction of a huge gaseous nebula. Today, this hypothesis provides the most widely accepted theory for how the solar system formed. Another of Laplace’s contributions to science was to analyze the complex forces of gravitational attraction between the planets. He investigated how these might affect the stability of the solar system and concluded that the system is inherently stable.

6 REMAINING DEBRIS

Radiation from the Sun blew away most of the remaining gas and other unaccreted material in the planetary solar system. Some of the leftover planetesimals in the outer part of the disk formed the vast and remote Oort Cloud of comets.

inner solar system

TH E S OL A R SY ST E M

IDA

The ring of planetesimals between Mars and Jupiter failed to form a planet, possibly because of the gravitational influence of Jupiter. Instead they formed a belt of asteroids, including this asteroid, Ida.

frozen cometary nuclei

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ROCK AND ICE PARTICLES

As they orbited the protosun, grains of dust and ice collided at low velocities and became stuck together. Over tens of millions of years, these particles grew to form the planetesimals.

dense, hot central region (protosun) protoplanetary disk

3 RINGS AND PLANETESIMALS

Instabilities in the rotating disk caused regions within it to condense into rings under the influence of gravity. Very gradually, planetesimals (small objects made of rock or rock and ice) formed in these rings through the accretion of much smaller particles. 2 FORMATION OF THE PROTOSUN

Under the influence of gravity, the solar nebula condensed into a dense central region (the protosun) and a diffuse outer region (the protoplanetary disk). As it contracted, the cloud began to spin faster and flattened out, and its central region heated up. GAS AND DUST

The cloud consisted mainly of hydrogen and helium gas, together with grains of dust containing some metals and substances such as water, methane, and ammonia.

planetesimals forming within rings

4 ROCKY PLANETS VENUS

Venus and the other inner rocky planets were formed in a molten state, because the collisions that led to their formation generated a huge amount of heat. Later, they partly solidified.

The planetesimals attracted each other by gravity and collided to build planets. Closest to the protosun, where it was extremely hot, only rocky material and metals could withstand the heat, so the planets formed in this region are made mainly of these materials. hot inner region of disk

5 GAS GIANTS

In the outer part of the disk, the bodies formed from planetesimals were made of rock and ice; they became big enough to attract large amounts of gas around them. Soon after these gas giants formed, the protosun became a full-fledged star.

accreting planetesimals

THE BIRTH OF THE PLANETS

cooler outer part of disk gas giant forming

Sun begins producing energy by nuclear fusion

In the gas giants, such as Jupiter and Saturn, a core of rock and ices formed first. These cores then attracted, and became enveloped by, large amounts of gas.

TH E SO LA R S Y S TE M

GAS-PLANET FORMATION

After tens of millions of years of planetesimal formation, the final stages of planet construction are thought to have happened relatively quickly, about 4.56 billion years ago. Once the planetesimals were a few miles in diameter, their gravity was strong enough to attract more and more material in a runaway process. Many of the planetesimals came together to form Moon-sized bodies called protoplanets, which finally underwent a series of dramatic collisions to form the rocky inner planets and the cores of the outer gas-giant planets. The latter, containing both rock and ice, were massive enough also to pull in vast amounts of hydrogen, helium, and other gases, which accreted onto the planetary cores to form dense atmospheres. Many of the leftover planetesimals are thought to have become comets and asteroids. Pluto may have formed from material not used in the gas giants, or it may have been captured by the solar system at a later time.

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THE FAMILY OF THE SUN

THE FAMILY OF THE SUN THE SOLAR SYSTEM CONSISTS OF

the Sun, eight recognized planets, over 140 moons, and countless 24–27 Celestial objects small bodies such as asteroids ands comets. Its inner 34–37 Radiation region contains the Sun and the rocky planets— 38–39 Gravity, motion, and orbits Mercury, Venus, Earth, and Mars. Beyond this lies 68–69 Planetary motion a ring of asteroids, called the Main Belt, and the The Milky Way 226–29 gas giant planets Jupiter, Saturn, Uranus, and Neptune. Next is a huge region populated by Pluto and other ice dwarfs and finally a vast cloud of comets. In total, the solar system is about 9.3 trillion miles (15 trillion km) across; the planets occupy a zone extending just 3.25 billion miles (6 billion km) from the Sun. 22–23 The scale of the universe

URBAIN LE VERRIER Urbain Le Verrier (1811-1877) was a French mathematician and astronomer who, after studying irregularities in the orbit of Uranus, predicted the existence of the planet Neptune, and calculated its position in 1846. He asked the German astronomer Johann Galle to look for Neptune, and within an hour the planet had been found.

ORBITS IN THE SOLAR SYSTEM Most orbits of objects in the solar system have the shapes of ellipses (stretched circles). However, for most of the planets, these ellipses are close to being circular. Only Mercury has an orbit that differs very markedly from being circular. All the planets and nearly all asteroids orbit the Sun in the same direction, which is also the direction in which the Sun spins on its own axis. The orbital period (the time it takes to orbit the Sun) increases with distance from the Sun, from 88 Earth days for Mercury to nearly 250 Earth years for Pluto, following a mathematical relationship first discovered by the German astronomer Johannes Kepler in the early 17th century (see p.68). As well as having longer orbits to complete, the planets farther from the Sun move much more slowly.

THE SUN The Sun's diameter at the equator is 864,900 miles (1.4 million km), and its equatorial rotation period is about 25 Earth days EARTH Orbits the Sun in 365.26 Earth days at an average distance of 92.9 million miles (149.6 million km)

TH E S OL A R SY ST E M

JUPITER Orbits the Sun in 11.86 Earth years at an average distance of 483.4 million miles (778.4 million km)

URANUS Orbits the Sun in 84.01 Earth years at an average distance of 1.8 billion miles (2.9 billion km)

PLANET ORBITS

All the orbits of the planets, and the Asteroid Belt, lie roughly in a flat plane known as the ecliptic plane. Only Mercury and the dwarf planet Pluto orbit at significant angles to this plane (7.0° and 17.1°, respectively). The planets and their orbits are not shown to scale here.

MERCURY Orbits the Sun in 88 Earth days at an average distance of 36.0 million miles (57.9 million km)

THE FAMILY OF THE SUN

THE GAS GIANTS

THE ROCKY PLANETS

The four large planets immediately beyond the Asteroid Belt are called the gas giants. These planets have many properties in common. Each has a core composed of rock and ice. This is surrounded by a liquid or semi-solid mantle containing hydrogen and helium, or, in the case of Uranus and Neptune, a combination of methane, ammonia, and water ices. Each has a deep, often stormy URANUS AND RINGS atmosphere composed mainly of Uranus has 11 major rings and a blue hydrogen and helium. All four have a coloration caused by the presence of significant magnetic field, but Jupiter’s is methane in its atmosphere (this is a exceptional, being 20,000 times stronger Hubble infrared image). Its spin axis than that of Earth. Each of the gas giants is tilted over on its side. is orbited by a large number of moons, several dozen in the case of Jupiter. Finally, all four gas giants have ring systems made of grains of rock or ice. These rings may have been present since the planets formed, or they may be the fragmented remains of moons that were broken up by the gas giants’ powerful gravitational fields.

The four inner planets of the solar system are also called the rocky planets. They are much smaller than the gas giants, have few or no moons, and no rings. All four were born in a molten state due to the heat of the collisions that led to their formation. While molten, the materials from which they are made became separated into a metallic core and a rocky mantle and crust. Throughout their later history, all these planets suffered heavy bombardment by meteorites that left craters on their surfaces, although on Earth these craters have largely become hidden by various geological processes. In some other respects, the rocky planets are quite diverse. For example, Venus has a dense atmosphere consisting mainly of carbon dioxide, while Mars has a thin atmosphere composed of the same gas. In contrast, Mercury has virtually no atmosphere and Earth’s is rich in nitrogen and oxygen. 6-mile- (10-km-) wide impactor

GOSSES BLUFF CRATER MARS Orbits the Sun in 687 Earth days at an average distance of 141.6 million miles (227.9 million km)

VENUS Orbits the Sun in 224.7 Earth days at an average distance of 67.2 million miles (108.2 million km)

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This impact crater in a central desert region of Australia resulted from an asteroid 0.6 miles (1 km) wide that smashed into Earth’s surface 142 million years ago.

MAIN BELT Lies between the orbits of Mars and Jupiter and is a source of meteorites; some asteroids orbit the Sun outside the Main Belt

IMPACTOR STRIKES front of impactor collapses

back of impactor continues forwards

EXPLOSION ON IMPACT crater 60 miles (100 km) wide and 7.5 miles (12 km) deep

rocks blast into atmosphere

SATURN Orbits the Sun in 29.46 Earth years at an average distance of 886 million miles (1.4 billion km)

CRATER FORMATION steep sides fall in

crater up to 150 miles (240 km) wide

DEEP IMPACT

NEPTUNE Orbits the Sun in 164.8 Earth years at an average distance of 2.8 billion miles (4.5 billion km)

This sequence shows what typically happens when a 6-mile- (10-km-) wide projectile hits a rocky planet or moon. The crater formed is much larger than the impactor. The latter usually vaporizes on impact, though some melted or shattered remnants may be left at the site.

TH E SO LA R S Y S TE M

CRATER COLLAPSE

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THE SUN

THE SUN 31 Nuclear fission and fusion 34–37 Radiation 67 Solar eclipses Stars 232–33 The life cycles of stars 234–37 Star formation 238–39 Main-sequence stars 250–51

THE SUN IS A 4.6-BILLION-YEAR-OLD

main-sequence star. It is a huge sphere of exceedingly hot plasma (ionized gas) containing 750 times the mass of all the solar system’s planets put together. In its core, nuclear reactions produce helium from hydrogen and generate colossal amounts of energy. This energy is gradually carried outward until it eventually escapes from the Sun’s surface.

INTERNAL STRUCTURE The Sun has three internal layers, although there are no sharp boundaries between them. At the center is the core, where temperatures and pressures are extremely high. In the core, nuclear fusion turns the nuclei of hydrogen atoms (protons) into helium nuclei at the rate of about 600 million tons per second. Released as byproducts of the process are energy, in the form of photons of electromagnetic (EM) radiation, and neutrinos (particles with no charge and almost no mass). The EM radiation travels out from the core through a slightly cooler region, the radiative zone. It takes about 1 million years to find its way out of this zone, as the photons are continually absorbed and reemitted by ions in the plasma. Farther out, the energy wells up in a convective zone—where huge flows of rising hot plasma occur next to areas of falling cooler plasma—and is transferred to a surface layer called the photosphere. There it escapes as heat, light, and other forms of radiation. chromosphere is an irregular layer of atmosphere above the photosphere photosphere is the Sun’s visible surface convective zone is a region where energy is carried by convection cells radiative zone, where energy travels in the form of photons core, where nuclear reactions occur

THE SUN’S STRUCTURE

The Sun’s interior consists of the core, the radiative zone, and the convective zone. Light and heat escape into space at the photosphere. The Sun is composed principally of hydrogen (71 percent by mass) and helium (27 percent).

TH E S O LA R S Y S TE M

SUN PROFILE

AVERAGE DISTANCE FROM EARTH

ROTATION PERIOD (POLAR)

93.0 million miles (149.6 million km)

34 Earth days

SURFACE TEMPERATURE

ROTATION PERIOD (EQUATORIAL)

9,932°F (5,500°C)

25 Earth days

CORE TEMPERATURE

MASS (EARTH = 1)

27 million °F (15 million °C)

SIZE COMPARISON

333,000

DIAMETER AT EQUATOR

864,900 miles (1.4 million km)

EARTH

OBSERVATION

The Sun has an apparent magnitude of –26.7 and should never be observed directly with the naked eye or any optical instrument. It can be observed safely only through special solar filters.

THE SUN

VIOLENT SUN

This composite image taken by the SOHO observatory shows both the Sun’s surface and its corona. When the corona image was taken, billions of tons of matter were being blasted through it into space.

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STUDYING THE SUN FROM SPACE Since 1960, a series of space probes and satellites have been launched by NASA and other organizations with the aim of collecting data about the Sun. Some of the most important missions are listed below. These were a series of probes that successfully orbited the Sun and studied the solar wind, solar flares, and the interplanetary magnetic field.

1960–68 PIONEERS 5 TO 9 (USA)

1974, 1976 HELIOS 1 AND 2 (USA AND GERMANY) The two Helios probes were

put into orbits that involved high-velocity passes close to the Sun’s surface. They measured the solar wind and the Sun’s magnetic field. 1980 SOLAR MAXIMUM MISSION (USA)

This studied the Sun at its most active, collecting X-rays, gamma rays, and ultraviolet radiation produced by flares, sunspots, and prominences. The first space probe to be sent into an orbit over the Sun’s poles, Ulysses has studied the solar wind and the Sun’s magnetic field over its polar regions.

1990 ULYSSES (USA AND EUROPE)

Yohkoh was an Earth-orbiting satellite that for 10 years observed high-energy radiation (X-rays and gamma rays) produced by solar flares, as well as pre-flare conditions.

1991 YOHKOH (JAPAN, USA, AND UK)

YOHKOH

SOHO

1995 SOHO (USA AND EUROPE) This

solar observatory follows a special “halo” orbit around the Lagrangian point 930,000 miles (1.5 million km) from Earth in the direction of the Sun. SOHO (solar and heliospheric observatory) studies the Sun’s interior and events at its surface. Trace is a satellite in Earth’s orbit that studies the corona and a thinner layer in the Sun’s atmosphere called the transition region. The objective of TRACE (transition region and coronal explorer) is to better understand the connection between the Sun’s magnetic field and coronal heating.

1998 TRACE (USA)

Relations Observatory consists of twin spacecraft that observe the Sun from different directions, giving all-round coverage of solar eruptions and the solar wind. 2010 SDO (USA) NASA’s

Solar Dynamics Observatory monitors the Sun to improve our understanding of its activity and to make better predictions of how this activity will affect Earth. SDO

TH E S OLA R S Y S TE M

2006 STEREO (USA) The Solar Terrestrial

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THE SUN CORONAL MASS EJECTION is a bubble of plasma ejected from the Sun into space

CORONA is hundreds of times hotter than the photosphere

GRANULATION is the mottling of the surface caused by convection cells

FACULAE are intensely bright active regions that are associated with the appearance of sunspots

SPICULES are short-lived jets of gas that are 6,000 miles (10,000 km) long

TH E S OL A R S Y ST E M

SOLAR ACTIVITY

This ultraviolet image of the Sun was obtained by an instrument onboard the SOHO solar observatory. It shows the Sun’s chromosphere (the layer just above the photosphere) and various protuberances, including a huge solar prominence, as well as a number of active regions on the solar surface. The image also shows a coronal mass ejection with a bright central area of ultraviolet emission.

SURFACE The visible surface of the Sun is called the photosphere. It is a layer of plasma (ionized gas) about 60 miles (100 km) thick and appears granulated or bubbly. The bumps, which are about 600 miles (1,000 km) wide, are the upper surfaces of convection cells that bring hot plasma up from the Sun’s interior. Other significant features of the photosphere are sunspots, which are cooler regions that appear dark against their brighter, hotter surroundings. SUNSPOTS Sunspots and related phenomena, such as Each sunspot has a dark central region, the umbra, and a lighter solar flares (tremendous explosions on the periphery, the penumbra. Away Sun’s surface) and plasma loops, are from the sunspots, the Sun’s thought to have a common underlying surface looks granulated. Each cause—they are associated with strong granule is the top of a convection magnetic fields or disturbances in these cell in the Sun’s interior. fields. The magnetic fields result from the fact that the Sun is a rotating body that consists largely of electrically charged particles (ions in its plasma). Different parts of the Sun’s convective zone rotate at different rates (faster at the equator than the poles), causing the magnetic field lines to become twisted and entangled over time. Sunspots are caused by concentrations of magnetic field lines inhibiting the flow of heat from the interior where they intersect the photosphere. Other types of disturbance are caused by twisted field lines popping out of the Sun’s surface, releasing tremendous energy, or by plasma erupting as loops along magnetic field lines. The amount of sunspot and related activity varies from a minimum to a maximum over an 11-year cycle.

PROMINENCE is a dense cloud of gas, suspended above the Sun’s surface by magnetic field loops, that may persist for days or even weeks

PHOTOSPHERE

The base of the photosphere has a temperature of 10,300°F (5,700°C) but its upper layers are cooler and emit less light. Here, the edge of the Sun’s disk looks darker because light from it has emanated from these cooler regions.

FIRST OBSERVATION OF A SOLAR QUAKE

2 The quake, equivalent to an In July 1996, by analyzing data obtained by an instrument on the earthquake of magnitude 11, was SOHO observatory, scientists recorded caused by a solar flare, visible as the a solar quake for the first time. white blob with a “tail” to its left.

1

4 Over the course of an hour, the The seismic waves looked like waves traveled a distance equal to ripples on a pond but were 2 miles 10 Earth diameters before fading (3 km) high and reached a maximum speed of 248,600 mph (400,000 km/h). into the fiery background.

3

THE SUN

JOSEPH VON FRAUNHOFER A German physicist and optical instrument maker, Joseph von Fraunhofer (1787–1826) is best known for his investigation of dark lines in the Sun’s spectrum. Now known as Fraunhofer lines, they correspond to wavelengths of light absorbed by chemical elements in the outer parts of the Sun’s atmosphere. Fraunhofer’s observations were later used to help determine the composition of the Sun and other stars.

ATMOSPHERE

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CHROMOSPHERE

As well as forming its visible surface, the photosphere is the lowest layer of the Sun’s atmosphere. Above it are three more atmospheric layers. The orangey-red chromosphere lies above the photosphere and is about 1,200 miles (2,000 km) deep. From the bottom to the top, its temperature rises from 8,100°F (4,500°C) to about 36,000°F (20,000°C). The chromosphere contains many flamelike columns of plasma called spicules, each rising up to 6,000 miles (10,000 km) high along local magnetic field lines and lasting for a few minutes. Between the chromosphere and the corona is a thin, irregular layer called the transition region, within which the temperature rises from 36,000°F (20,000°C) to about 1.8 million °F (1 million °C). Scientists are studying this region in an attempt to understand the cause of the temperature increase. The outermost layer of the solar atmosphere, the corona, consists of thin plasma. At a great distance from the Sun, this blends with the solar wind, a stream of charged particles (mainly protons and electrons) flowing away from the Sun across the solar system. The corona is extremely hot, 3.6 million °F (2 million °C), for reasons that are not entirely clear, although magnetic phenomena are believed to be a major cause of the heating. Coronal mass ejections (CMEs) are huge bubbles of plasma, containing billions of tons of material, that are occasionally ejected from the Sun’s surface through the corona into space. CMEs can disturb the solar wind, which results in changes to aurorae in Earth’s atmosphere (see p.74).

The Sun’s chromosphere is visible here as an irregular, thin red arc adjacent to the much brighter photosphere. Also apparent is a flamelike protuberance from the chromosphere into the corona.

CORONA

The outermost layer of the Sun, the corona extends outward into space for millions of miles from the chromosphere. It is most easily observed during a total eclipse of the Sun, as here.

CORONAL MASS EJECTION

This image of a coronal mass ejection (top left) was taken by the SOHO solar observatory, using a coronagraph—an instrument that blocks direct sunlight by means of an occulter (the central smooth red area in the image). The white circle represents the occulted disk of the Sun.

MAGNETIC ERUPTION

Hot plasma explodes into the atmosphere, following magnetic field lines. In this TRACE image, colors represent temperature, with blue being the coolest, red the hottest.

When charged particles from the solar wind reach Earth, they can cause aurorae. This photograph of the aurora borealis was taken in Manitoba, Canada.

These three images of a magnetically active solar region, taken by the TRACE satellite, span a period of 2.5 hours. The loops in the Sun’s corona probably followed a solar flare and consist of plasma heated to exceedingly high temperatures along magnetic field lines.

TH E S O LA R S Y S TE M

POST-FLARE LOOPS NORTHERN LIGHTS

MAGNETIC DISTURBANCE

Active regions are areas on the Sun where magnetic fields burst through the Sun’s visible surface, causing dark sunspots and bright areas called faculae. Active Region 1429, seen here, appeared in March 2012 and fired off flares and coronal mass ejections that caused spectacular aurorae on Earth. In this false-color image, the dark regions are the hottest and brightest.

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MERCURY

MERCURY MERCURY IS THE SECOND-SMALLEST

planet in the solar system, the closest planet to the Sun, and the richest in iron. 68–69 Planetary motion The surface environment is extremely harsh. There is hardly 100–101 The history of the Solar System any shielding atmosphere, and the temperature rises to a 102–103 The family of the Sun blistering 800°F (430°C) during the day, then plummets to an air-freezing –290°F (–180°C) at night. No other planet experiences such a wide range of temperatures. Its surface has been churned up by meteoritic bombardment and is dark and dusty. 38–39 Gravity, motion, and orbits

ORBIT With the exception of Pluto, TRANSIT OF MERCURY Mercury has the most eccentric Mercury passes directly between Earth and the of all the planetary orbits. At Sun about 13 times a perihelion it is only 28.6 million century. This row of dots miles (46 million km) from the is a multiple exposure of Sun, but at aphelion it is 43.3 Mercury’s transit across million miles (69.8 million km) the Sun in 2006. away. The plane of Mercury’s equator coincides with the plane of its orbit (in other SPIN AND ORBIT words, its axis of rotation is almost vertical). This Mercury rotates three times in two means that the planet has no seasons, and that some orbits (in other words, there are three Mercurian “days” in two Mercurian craters close to the poles never receive any sunlight “years”). This unusual spin–orbit and are permanently cold. The orbit is inclined at 7° coupling means that for an observer to the plane of the Earth’s orbit. Because Mercury standing on Mercury there would be orbits inside the Earth’s orbit, it displays phases, just an interval of 176 Earth days between like the Moon (see p.62). one sunrise and the next.

planet spins on its axis every 58.65 Earth days

axial tilt is almost vertical Sun

PERIHELION 29 million miles (46 million km)

APHELION 43 million miles(70 million km)

Mercury orbits Sun in 88 Earth days

EXPLORING SPACE

TH E S O LA R S Y S TE M

EINSTEIN AND MERCURY perihelion moves with each orbit

Mercury’s perihelion position moves slightly more than Isaac Newton’s theories of motion predict. In the 19th century, it was proposed that a planet (called Vulcan) inside Mercury’s orbit produced this effect. In his general theory of relativity of 1915, the German physicist Albert Einstein suggested that space near the Sun was curved and correctly predicted the exact amount by which the perihelion would move.

Sun

POCKMARKED PLANET MERCURY’S WOBBLY ORBIT

Mercury’s perihelion advances by about 1.55° every century, which is 0.012° more than is expected given the gravitational influence of nearby planets.

orbital path aphelion

Mercury’s heavily cratered surface, seen here from the Messenger probe in 2009, resembles the highland areas of the Moon. The planet also has large expanses of younger, smooth, lightly cratered plains, rather like the lunar maria.

MERCURY rocky, silicate mantle

crust of silicate rock

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STRUCTURE

The very high density of Mercury indicates that it is rich in iron. This iron sank to the center some 4 billion years ago, producing a huge core, 2,235 miles (3,600 km) in diameter. There is a possibility that a thin layer of the outer core is still molten. The solid rocky mantle is about 340 miles (550 km) thick and makes up most of the outer 25 percent of the planet. This outer mantle has slowly cooled, and during the last billion years volcanic eruptions and lava flows have ceased, making the planet tectonically inactive. The mantle and the thin crust mainly consist of the silicate mineral anorthosite, just like the old lunar highlands. There are no iron oxides. Unlike MERCURY INTERIOR on other planets, it seems that all the iron has Compared to the other rocky gone into the core, which produces a planets, Mercury is very rich in metals magnetic field with a strength that is about and poor in heat-producing radioactive one percent of Earth’s magnetic field. elements. Its huge iron core is probably solid. iron core

potassium and other gases (1%)

ATMOSPHERE

sodium (39%)

oxygen (52%)

helium (8%)

Mercury has a very thin temporary atmosphere because the planet’s mass is too small for an atmosphere to persist. Mercury is very close to the Sun, so daytime temperatures are extremely high, reaching 810°F (430°C). The escape velocity is less than half that of Earth, so hot, light elements in the atmosphere, such as helium, quickly fly off into space. All the atmospheric gases therefore need constant replenishment. Mercury’s atmosphere was analyzed by an ultraviolet spectrometer onboard the Mariner 10 spacecraft in 1974. Oxygen, helium, and hydrogen were detected in this way, and subsequently atmospheric sodium, potassium, and calcium have been detected by Earth-based telescopes. The hydrogen and helium are captured from the solar wind of gas that is constantly escaping from the Sun. The other elements originate from the planet’s surface and are intermittently kicked up into the tenuous atmosphere by the impact of ions from Mercury’s magnetosphere and micrometeorite particles from the solar system dust cloud. The atmospheric gases are much denser on the cold night side of the planet than on the hot day side, as the molecules have less energy to escape.

ATMOSPHERIC COMPOSITION

Oxygen is the most abundant gas, followed by sodium and helium. However, loss and regeneration of the gases is continuous, and the atmospheric composition can vary drastically over time. northern hemisphere

DAY 1

direction of sunlight southern hemisphere DAY 2

MERCURY’S SODIUM TAIL

Pressure exerted by sunlight pushes sodium atoms away from Mercury, forming a “tail” some 25,000 miles (40,000 km) long. Mercury and the Sun are off to the left in this falsecolored view of Mercury’s sodium tail. Emissions from this tail have previously been observed with Earthbased telescopes, but this image from a spectrometer on board Messenger is the most detailed image yet.

night side of Mercury

cloud of sodium vapor

DAY 3

MERCURY PROFILE

ROTATION PERIOD

36 million miles (57.9 million km)

59 Earth days

SURFACE TEMPERATURE

ORBITAL PERIOD (LENGTH OF YEAR)

–290°F to 810°F (–180°C to 430°C)

sodium cloud has disappeared

88 Earth days

DIAMETER

3,029 miles (4,875 km)

MASS (EARTH = 1)

0.055

TEMPORARY ATMOSPHERE

VOLUME (EARTH = 1)

0.056

GRAVITY AT EQUATOR (EARTH = 1)

0.38

NUMBER OF MOONS

0

SIZE COMPARISON

Thin clouds of sodium suddenly appear over some regions of Mercury and then just as quickly disappear, as seen in these false-color observations made by the Kitt Peak Solar Observatory, USA. The clouds might be produced by meteorite impacts – the freshly cratered surface releases sodium vapor when it is next heated by sunlight. Another possibility is that ionized particles actually hit Mercury’s surface and release sodium from the regolith.

OBSERVATION

Never more than 28° away from the Sun in the sky, Mercury is always seen at dawn or dusk. It is the most difficult of the nearby planets to spot and is visible only for a few days each month.

EARTH

MERCURY

TH E S OLA R S Y S TE M

AVERAGE DISTANCE FROM THE SUN

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MERCURY meteorite strikes Mercury, forming the Caloris Basin

shock waves spread over surface

SURFACE FEATURES

Impact craters cover Mercury’s visible surface. As the surface gravity is about twice that of the Moon, the ejecta blankets are closer to the parent craters and thicker than those found on the Moon. Large meteorite impacts have produced multiring basins. A particularly impressive example is the Caloris Basin. On the opposite side of the planet to the basin is a region of strange terrain produced by earthquakes resulting SURFACE COMPOSITION from the impact (see left). The craters are interspersed by at In this false-color mosaic, yellow represents areas of least two generations of flat plains of solidified basaltic lava, the silicate crust that have like the lunar maria. Fluid lava oozed gently out of vents in been exposed by cratering, the crust and pooled in depressions. Eventually, most of the while the blue regions are vents were covered by the lava. The Messenger space probe younger volcanic rocks. has photographed volcanic vents around the perimeter of the Caloris basin, which are evidently the source core’s diameter surface shrank by up to of these lavas. Mercury’s surface also has several compressed 2.5 miles (4 km) shock waves ridges, which are up to 0.6–1.9 miles (1–3 km) converge and high and 310 miles (500 km) long. shatter surface

ejecta

opposite impact site original size

RIDGE FORMATION

shock waves travel through core

Mercury uniquely has steep, clifflike north–south ridges stretching all over the surface. There are two probable causes. Tidal forces slowed the planet’s rotation, changing its shape from ovoidal to spherical. Also, as Mercury cooled, it shrank, decreasing its diameter by 0.1 percent. The surface was compressed, and parts of the crust were pushed over adjacent areas.

IMPACT SHOCK WAVES

CHAOTIC TERRAIN OPPOSITE THE CALORIS BASIN

GEOGRAPHY

ridges formed where crust crumpled

Verdi Brahms Zola Dali

Poe

Shakespeare

Van Eyck

Munch

Brontë

Degas

CA LORIS MONT E S

Cunningham

ms Rup kerck es

Mariner 10 photographed less than half the surface of Mercury, but Messenger has now shown us the whole planet, and in greater detail. The 20° longitude meridian passes exactly through the center of a small crater that has been named Hun Kal, which means “20” in the Mayan language. Other craters have been named after famous artists, authors, and musicians, such as Michelangelo, Dickens, and Beethoven. Most of the plains are named after the word for the planet Mercury in various languages.

Couperin

Caloris Basin

ODIN PLANITIA

BUDH PLANITIA

Hee

A few minutes after the formation of the Caloris Basin, the shock waves generated by the impact came to a focus on the opposite side of the planet. This caused a massive upheaval over an area of 96,500 square miles (250,000 square kilometers), raising ridges up to 1.1 miles (1.8 km) high and 3–6 miles (5–10 km) across. Crater rims were broken into small hills and depressions.

EXPLORING SPACE

Messenger (the Mercury Surface, Space Environment, Geochemistry, and Ranging mission) is only the second space probe to Mercury, the first having been Mariner 10 in 1974. Launched by NASA in 2004, Messenger carries cameras and instruments to map the tiny inner planet in detail, as well as to study its surface composition, geological history, magnetic field, and tenuous atmosphere. MESSENGER

Phidias

Mozart Raden Saleh

TIR PLANITIA

Qi Baishi

Po Chu I

Sophocles

Moody Liszt

Tolstoj Beethoven

Milton Bartok

magnetometer

Basho Gainsborough

Dostoevsky

antenna

N

Delacroix

MERCURY MAP solar panel

One hemisphere of Mercury is seen in a mosaic of Messenger images. Mercury was previously mapped by Mariner 10.

H Ru ero pe s

TH E S OL A R SY ST E M

MESSENGER

270°

180°

90°

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FEATURES OF MERCURY Mercury is covered with impact craters ranging in size from small, bowl-shaped craters to a basin that is a quarter of the diameter of the planet. Its flat plains (called planitiae) were formed when lava flooded low-lying regions. In the last billion SOUTH POLE years, the impact rate has greatly The temperature is permanently freezing in decreased, volcanism has ceased, and Mercury’s south polar region because it the surface has changed little. receives very little sunlight. SHAKESPEARE REGION

Caloris Basin Impact crater

TYPE

AGE

4 billion years

DIAMETER

840 miles

(1,350 km) MESSENGER MAP

The formation of this huge multi-ring basin, which is larger than the US state of Texas, was a major event in the early history of the planet. It is similar to the Orientale Basin on the Moon. The asteroid responsible for creating the basin was probably about 60 miles (100 km) across. Ejecta were thrown more BASIN FLOOR

The lava-filled basin floor is wrinkled with ridges and furrows and pitted with impact craters of varying sizes.

SHAKESPEARE REGION

Brahms Crater TYPE

than 620 miles (1,000 km) beyond the outer rim, producing many radial ridges. The tremendous impact that produced Caloris led to seismic waves being focused on the opposite side of the planet, causing an earthquake. The waves were then reflected back to the basin and fractured the surrounding rocks. Caloris was probably produced toward the end of the period of massive bombardment. Subsequently, the basin floor filled with lava, which cooled and fractured in a polygonal fashion, creating the lowland called Caloris Planitia. The basin is now about 1.2 miles (2 km) deep. Mariner 10 discovered the basin, but it was not photographed in full until Messenger arrived. The name “Caloris” is derived from the Latin for heat, and as the Sun is overhead at perihelion, the basin is one of the two hottest places on Mercury.

Impact crater

AGE

500 million years

DIAMETER

37 miles

(60 km) MESSENGER MAP

MESSENGER MAP

2 billion years

310 miles (500 km)

LENGTH

MARINER 10 MAP

This clifflike ridge (rupes in Latin), which in places is 1.2 miles (2 km) high, is younger than both the craters and the volcanic plains that it crosses. Discovery runs in a northeast–southwest direction and, at 310 miles (500 km) in length, it is the longest cliff on Mercury. It was formed when part of the rocky crust cracked and was lifted up as the planet cooled and shrank. Discovery is one of 16 cliff systems that have been discovered on Mercury to date. IMPACT BASIN

A false-color image reveals that the floor of the Caloris impact basin (orange) differs in composition from the surrounding plains.

Bach Crater

TYPE

Ridge

AGE

Degas Crater 60 miles (97 km)

TYPE

Impact crater

AGE

4 billion years

DIAMETER

133 miles

(214 km) MARINER 10 MAP

This bright ray crater is relatively young, and it overlies the slightly larger Brontë crater to its north. The rays extend out radially for several hundred miles, crossing all other features. These highly reflective, wispy streaks were caused by the fine pulverized rock ejected from Degas churning up the soil surface on impact. It will take about a billion years for the solar wind to erase them.

This two-ringed basin represents an intermediate class of craters, between the slightly smaller ones with central mountainous peaks and larger ones with multiple rings. The prominent inner ring is half the width of the outer, and the overall circularity is impressive. Bach was formed toward the end of the period of heavy bombardment. Lava later flooded the crater, producing the smooth floor.

RAY CRATER

TWO-RINGED BASIN

CENTRAL PEAK

This 2-mile- (3-km-) high mountain was produced when the subsurface rock rebounded after being struck by an asteroid.

DISCOVERY RUPES CUTTING THROUGH IMPACT CRATERS

TH E SO LA R S Y S TE M

A large, mature, complex crater to the north of the Caloris Basin, Brahms has a prominent central mountainous peak about 12 miles (20 km) across. The walls have slipped inward, forming a series of elaborate, concentric, stairlike terraces and a highly irregular rim. This structure is typical of a crater this size—craters with diameters less than 6 miles (10 km) are bowl-shaped, and craters with diameters greater than 80 miles (130 km) develop central rings (see Bach, right). Radial hills of ejecta surround Brahms.

TYPE

BEETHOVEN REGION

3.5 billion years

DIAMETER

Discovery Rupes

SHAKESPEARE REGION

Impact crater

AGE

RENOIR REGION

114

VENUS

VENUS VENUS IS THE SECOND PLANET FROM THE SUN

and Earth’s inner neighbor. The two planets are virtually 68–69 Planetary motion identical in size and composition, but these are very 100–101 The history of the solar system different worlds. An unbroken blanket of dense 102–103 The family of the Sun clouds permanently envelops Venus. Underneath lies a gloomy, lifeless, dry world with a scorching surface, hotter than that of any other planet. Radar has penetrated the clouds and revealed a landscape dominated by volcanism. 38–39 Gravity, motion, and orbits

ORBIT Venus’s orbital path is the least elliptical of all the planets. It is almost a perfect circle, so there is little difference between the planet’s aphelion and perihelion distances. Venus takes 224.7 Earth days to complete one orbit. As it orbits the Sun, Venus spins extremely slowly on its axis— slower than any other planet. It takes 243 Earth days for just one spin, which means that a Venusian day is longer than a Venusian year. However, the time between one sunrise and the next on Venus is 117 Earth days. This is because the planet is traveling along its orbit as it spins, and so any one spot on the surface faces the Sun every 117 Earth days. Venus’s slow spin is also in the opposite direction from most other planets. Venus does SPIN AND ORBIT not have seasons as it moves through its orbit. Venus is tipped over by This is because of its almost circular path and 177.4°. This means its spin axis is tilted by just the planet’s small axial tilt. Venus’s orbit lies 2.6° from the vertical. As inside that of the Earth, and about every 19 a result, neither of the months Venus moves ahead of Earth on its planet’s hemispheres nor inside track and passes between our planet and poles points markedly the Sun. At this close encounter, Venus is toward the Sun during the course of an orbit. within 100 times the distance to the Moon. spins on its axis every 243 Earth days

South Pole

PERIHELION 66.8 million miles (107.5 million km)

APHELION 67.6 million miles (108.9 million km)

Sun

orbits the Sun in 224.7 Earth days

TH E S OL A R S YS TEM

STRUCTURE

axis tilts from vertical by 2.6˚

planet is tilted by 177.4˚ so the North Pole is at the bottom of the globe

Venus is one of the four terrestrial planets and the most similar of the group to Earth. It is a dense, rocky world just smaller than Earth and with less mass. Venus’s Earth-like size and density leads scientists to believe that its internal structure, its core dimensions, and the thickness of its mantle are also similar to Earth’s. So Venus’s metal core is thought to have a solid inner part and a molten outer part, like Earth’s core. In contrast to Earth, Venus has no detectable magnetic field. The planet spins extremely slowly compared to Earth, far too slowly to produce the circulation of the molten core that is needed to generate a magnetic field. Venus’s internal heat—generated early in the planet’s history and from radioactive decay in the mantle—is lost through the crust by conduction and volcanism. Heat melts the subsurface mantle material, and magma is released onto the surface.

silicate crust

rocky mantle

molten iron and nickel outer core

solid iron and nickel inner core

VENUS INTERIOR

Venus was formed from the same material as Earth about 4.5 billion years ago and has differentiated into distinct layers in much the same way. A substantial part of the core has solidified; the exact amount still molten is unknown.

VENUS TERRIBLE BEAUTY

Venus’s thick, reflective clouds cause the planet to shine brightly, so that from a distance it looks beguiling and beautiful, which is why it was named after the Roman goddess of love and beauty. Close up, it is a different story; no human could survive on this planet.

115

VENUS PROFILE

AVERAGE DISTANCE FROM THE SUN

ROTATION PERIOD

67.2 million miles (108.2 million km)

243 Earth days

SURFACE TEMPERATURE

ORBITAL PERIOD (LENGTH OF YEAR)

867°F (464°C)

224.7 Earth days

DIAMETER

7,521 miles (12,104 km)

MASS (EARTH = 1)

0.82

VOLUME (EARTH = 1)

0.86

GRAVITY AT EQUATOR (EARTH = 1)

NUMBER OF MOONS

0

SIZE COMPARISON EARTH

OBSERVATION

0.9 VENUS

Venus is the brightest planet in Earth’s sky and is surpassed in brightness only by the Sun and the Moon. Its maximum magnitude is –4.7. It is seen in the early morning or early evening sky.

carbon dioxide 96.5%

ATMOSPHERE

nitrogen and trace gases 3.5%

COMPOSITION OF ATMOSPHERE

Along with carbon dioxide and

nitrogen, Venus’s atmosphere Venus’s carbon-dioxide-rich contains traces of other gases, atmosphere stretches up from the such as water vapor, sulfur ground for about 50 miles (80 km). dioxide, and argon. A deck of clouds with three distinct layers lies within the atmosphere. The lowest layer is the densest and contains large droplets of sulfuric acid. The middle layer contains fewer droplets, and the top layer has small droplets. Close to the planet’s surface, the atmosphere moves very slowly and turns with the planet’s spin. Higher up, in the cloudy part of the atmosphere, fierce winds blow westward. The clouds speed around Venus once every four Earth days. The clouds reflect the majority of sunlight reaching Venus back into space, and so this is an overcast, orange-colored world. Venus’s equator receives more solar heat than its polar regions. Yet the surface temperature at the equator and the poles varies by only a few degrees from 867°F (464°C), as do the day and night temperatures. The initial difference generates cloudtop winds that transfer the heat to the polar regions about 80 percent of sunlight in one large reflects away circulation cell. As a result, Venus cloud deck stretches from has no weather. about 28 miles (45 km) to about 43 miles (70 km) above the ground

reflected light means cloud surface is bright and easy to see

infrared radiation is absorbed by carbon dioxide and cannot escape into space

20 percent of sunlight reaches rocky surface

MIDDLE CLOUD LAYER

In this infrared image of Venus, heat from the lower atmosphere shines through the sulfuric acid clouds. The colors indicate the relative transparency of the middle cloud layer: white and red are thin clouds; black and blue are thick.

GREENHOUSE EFFECT

Venus’s thick cloud layers trap heat and help produce the planet’s high surface temperature in the same way that glass traps heat in a greenhouse. Only 20 percent of sunlight reaches the surface. Once there, it warms up the rock. Heat in the form of infrared radiation is then released, but it cannot escape and adds to the warming process.

TH E S OL A R S Y S TE M

thick layers of sulfuric acid clouds stop most sunlight from reaching the surface

carbon dioxide in atmosphere holds in heat

116

VENUS

MISSIONS TO VENUS Over 20 probes have investigated Venus. The first was the USA’s Mariner 2, which made the first successful flyby of a planet in December 1962. Since then, probes have orbited Venus, plunged into its atmosphere, and landed on its scorching hot surface. Sixteen different Venera probes traveled to Venus between 1961 and 1983. Venera 4 parachuted through Venus’s atmosphere in October 1967 and returned the information that it is primarily composed of carbon dioxide.

1967 VENERA 4 (USSR)

VENERA 4

This was the first probe to make a controlled landing on the surface. An instrument capsule landed on the night side and measured the temperature.

1970 VENERA 7 (USSR)

TECTONIC FEATURES Venus could be expected to have global features similar to those on Earth, but it differs in one key respect: it does not have moving plates. This means that its surface tends to move up or down rather than sideways. Yet Venus displays many familiar, Earth-like features formed by a range of tectonic processes, as well as some unfamiliar ones, such as arachnoids (see below). Venus has hundreds of FRACTURES volcanoes, from large, shallow-sloped shield volcanoes This complex network of narrow such as Maat Mons, to small nameless domes. About fractures extends over about 30 miles (50 km) of northwest 85 percent of the planetary surface is low-lying Aphrodite Terra. It is reminiscent volcanic plains consisting of vast areas of flood lava. of a river system on Earth, but There has been volcanic activity as recently as about the angular intersections 500 million years ago, and it is possible that some of indicate this is a tectonically the volcanoes could be active. Other features are a formed system of fractures. result of the crust pulling apart or compressing. There are troughs, rifts, and chasms, as well as mountain belts such as Maxwell Montes, ridges, and rugged highland regions. Venus’s highest mountains and biggest volcanoes are comparable in size to the largest on Earth, but overall this planet LAVA FLOWS has less variation in height. Solidified lava flows spread out

The first image of the surface came from Venera 9. Its lander touched down on October 22, 1975 and returned an image of rocks and soil. Venera 10 did the same three days later.

for hundreds of miles in all directions from one of Venus’s many volcanoes. The colors represent levels of heat radiation.

SHIELD VOLCANO

1975 VENERA 9 AND 10 (USSR)

Venus’s tallest volcano, Maat Mons, rises to almost 3 miles (5 km) above the surrounding terrain and is 5 miles (8 km) above the planet’s mean surface level.

ARACHNOID Two Pioneer Venus probes, each with several components, arrived in 1978. An orbiter collected data that was used to make the first global map of Venus, and probes studied the atmosphere. 1978 PIONEER VENUS (USA)

This spiderlike volcanic feature has a central circular depression (or dome) surrounded by a raised rim with radiating ridges and valleys.

1981 VENERA 13 (USSR) Venera 13 survived on the surface for 2 hours 7 minutes on March 1, 1982. It took the first color images and analyzed a soil sample. Flat slabs of rock and soil can be seen beyond the edge of the probe in the image below.

LAKSHMI PLANUM

I S H TA R

Sachs Patera

TERRA

Fortuna Tessera Cleopatra Crater

Maxwell Montes Sacajawea Patera

LE

Jeanne Crater

DA AN IA

Sif Mons

Between September 1990 and October 1994, Magellan made four 243-day mapping cycles of Venus. It collected gravity data on the fourth cycle.

NIOB PLANI

BELL REGIO

IT

BELL REGIO

TELLUS TESSERA

LEDA PLANITIA

PL

GUINEVERE PLANITIA

LOUHI PLANITIA

Gula Mons

1990 MAGELLAN (USA)

Cunitz Crater

Heng-o Corona

T I N AT I N PLANITIA

N AV K A PLANITIA

VENUS EXPRESS

Danilova Crater Saskia Crater

A P H RO D I T E TERRA

Aglaonice Crater

es

AINO PLANITIA

Stein Crater N

90°

OVDA REGIO

APHRODITE TERRA

ALPHA REGIO

L A DA T E R R A

0°

90°

Alcott Crater S

Riley Crater

ia

K Ch ua as ma m a

N

0°

st

p

TH E S OL A R SY ST E M

Mead Crater

Ru

Launched in 2005, the European Space Agency’s Venus Express went into a highly elliptical orbit (passing over the planet’s poles) in 2006 to monitor its clouds, atmospheric circulation, and magnetic field.

These four views combine to show the complete surface of Venus. They have been labeled to show surface features, 270° such as mountains, craters, highland regions, upland areas, and lowland plains.

Pavlova Corona

He

2005 VENUS EXPRESS (EUROPE)

VENUS MAPS

EISTLA REGIO

S

180°

L A DA T E R R A

VENUS

IMPACT CRATERS

WIND STREAK

Although many hundreds of impact craters have been identified on Venus, this total is low compared to that for the Moon and Mercury. There were more craters in the past, but they were wiped out by resurfacing due to volcanic activity about 500 million years ago. Venus’s craters have some characteristics not seen elsewhere in the solar system, because its dense atmosphere and high temperature affect the incoming impactor and crater ejecta. Ejyecta can, for example, be blown by winds and form fluidlike flows. And some potential impactors are too small to reach the surface intact. They break up in the atmosphere, and either a resultant shock wave pulverizes the surface or a blanket of fine material formed by the breakup produces a DARK HALO A dark halo surrounds a bright dark halo mark before a feature that appears to be a crater forms. Wind has also cluster of small impacts, modified the surface, ejecta, and debris formed by creating wind streaks and an impactor that broke up in what may be sand dunes. the atmosphere.

UNUSUAL CRATER

This small crater, about 4 miles (6 km) across, has terraced walls and lobes of ejecta radiating out from the rim to give it an unusual starfishlike appearance.

117

A 22-mile- (35-km-) long tail of material has been created on the northeast side of this small volcano by prevailing winds.

WIND EROSION

Impact debris thrown 300 miles (500 km) to the northeast of Mead Crater has been modified by surface winds. Wind streaks are visible, but it is not known if these are bright streaks on dark terrain, or vice versa.

GEOGRAPHY Present maps of Venus are based on data collected by the Magellan probe (see panel, opposite), with additional information from previous missions. The coloring of the maps below and Magellan images is based on the colors recorded by Venera 13 and 14. The orange color is due to the atmosphere filtering out the blue light. The following terminology is used for the surface features: lowland plains are termed planitia; high plains, planum; extensive landmasses, terra; TOPOGRAPHIC MAP mountain ranges, montes; and This relief map, based on Pioneer Venus mountains or volcanoes, mons. A data, covers the surface area from chasma is a deep, elongated, steep-sided approximately 78°N to 63°S. High land is colored yellow, with the highest of depression. The features are all named all in red. The green-colored massifs of after women, both historical and Ishtar Terra (top) and Aphrodite Terra mythological, with the exception of (right) stand out from the surrounding lowland shown in blue. Maxwell Montes (see p.118). Wanda Crater Akna Montes

ATALANTA PLANITIA

VINMARA PLANITIA

VELLAMO PLANITIA

KAWELU PLANITIA

BE TIA

ASTERIA REGIO

ax rn s Fo upe R

Maria Celeste Crater Greenaway Crater

G

ULFRUN REGIO

an

e

as

m

a

BETA REGIO

has is C

a

n

Sapas Mons

Hecat

h sC

Ch

m

Maat Mons

Miralaidji Corona a a sm C h a s m Da l i C h a a n a i D

Atete Corona

PHOEBE REGIO

is Ch asma

Stanton Crater

N

90°

180°

Artemis Corona

m Arte

Isabella Crater N

IMDR REGIO 270°

NSOMEKA PLANITIA

180°

270°

Addams Crater S

S

THEMIS REGIO

0°

HELEN PLANITIA

N AV K A PLANITIA

TH E SO LA R S Y S TE M

RUSALKA PLANITIA

a

asma

THETIS REGIO

Ozza Mons

RUSALKA PLANITIA

GUINEVERE PLANITIA

D e va

ULFRUN REGIO

ATLA REGIO

Balch Crater

118

VENUS

TECTONIC FEATURES Thanks to space-probe exploration, astronomers have a full and detailed picture of Venus’s varied landscape. The planet has three main highland regions, termed terra. They are Aphrodite, which dominates the equatorial zone, and Lada and Ishtar. Over 20 smaller, upland areas, termed regio, are found around the planet. Extensive lowland plains, termed planitia, complete the global picture. Volcanic activity is evident across most of the VOLCANIC TERRAIN surface but the volcanoes are not randomly distributed. This view across western Eistla is typical of the Venusian There are more in the uplands, particularly in Atla and Regio surface. The volcanoes on the skyline Beta Regio, than in the highlands or plains. are Sif Mons (left) and Gula Mons.

LAVA CHANNEL

ISHTAR TERRA

Ishtar Terra TYPE

Highland terrain

Under 500 million years AGE

LENGTH 3,485 miles (5,610 km)

Ishtar Terra is a large plateau about the size of Australia, which stands 2 miles (3.3 km) above the surrounding lowlands. It is the nearest thing on

ISHTAR TERRA

Running for well over 1,200 miles (2,000 km), this lava channel is unusually long.

ISHTAR TERRA

Akna Montes TYPE

Fortuna Tessera Mountain range

Under 500 million years AGE

Venus to the continents on Earth. Its western region is the elevated plateau Lakshmi Planum, which is bounded at the northwest by the Akna Montes and the Freyja Montes, and to the south by the Danu Montes. The steep-sided Maxwell Montes range makes up the eastern part of Ishtar Terra, along with a deformed area, Fortuna Tessera, to the mountain range’s north and east. The plateau was possibly formed as areas of planetary crust were driven together. It is likely that beneath Ishtar there is cooled, thickened crust that is kept up by a rising region of mantle.

LENGTH

515 miles (830 km)

Forming the western border of Lakshmi Planum, Akna Montes is a ridge belt that appears to be the result of folding due to northwest–southeast compression. The mountain-building is thought to have occurred after the plains formed, as the plains in this region seem to be deformed.

MASSIVE PLATEAU

Looking eastward across Ishtar Terra, this false-color view, created from Pioneer-Venus 1 data, highlights the varying height of the terrain. Blue represents the lowest elevation, and red is the highest.

ISHTAR TERRA

Lakshmi Planum TYPE

Volcanic plain

Under 500 million years AGE

LENGTH 1,456 miles (2,345 km)

TH E S OL A R SY ST E M

The western part of Ishtar Terra consists of Lakshmi Planum. This is a smooth plateau, 2.5 miles (4 km) high, formed by extensive volcanic

eruptions. The plateau is encircled by curving mountain belts—the Danu, Akna, Freyja, and Maxwell Montes— and steep escarpments such as Vesta Rupes to its southwest. This massive plain covers an area that is about twice the size of Earth’s Tibetan Plateau (see pp.132–33). Two large volcanic features, the Colette Patera and Sacajawea Patera (see opposite), which punctuate the otherwise relatively smooth plain, were identified in Venera 15 and 16 data. Their floors lie over 1.5 miles (2.5 km) below the plateau level. There are just a few planums on Venus, all named after goddesses. Lakshmi is the Indian goddess of love and war.

FOLDING DUE TO COMPRESSION

ISHTAR TERRA

Maxwell Montes TYPE

Mountain range

Under 500 million years AGE

LENGTH

495 miles (797 km)

The Maxwell Montes mountain range forms the eastern boundary of Lakshmi Planum. It is the highest point on Venus, rising over 6 miles (10 km) above the surrounding lowlands. In its

LAVA FLOWS

The eastern Lakshmi region is covered by lava flows. The dark flows are smooth, and the light ones are rough in texture. A bright impact crater can be seen on the right.

STEEP SLOPES

This computer-generated image, looking eastward toward the Maxwell Montes, has been colored to show the presence of iron oxides on the surface.

TYPE

Ridged terrain

Under 500 million years AGE

LENGTH 1,739 miles (2,801 km)

Fortuna Tessera is an area of north–southtrending ridges about 600 miles (1,000 km) wide. The distinctive pattern made by the region’s intersecting ridges and grooves led to this type of terrain originally being called parquet terrain, after its resemblance to woodblock flooring, RIDGES although it is now termed tessera. The image here is a view looking westward across about 155 miles (250 km) of Fortuna Tessera toward the slopes of Maxwell Montes (colored in blue). higher regions, the ridges, which are 6–12 miles (10–20 km) apart, have a sawtooth pattern. The mountains fall away to Fortuna Tessera to the east. The western side is a complex of grooves and ridges and is particularly steep— Magellan data revealed that the southwestern flank has a slope of 35°. The mountain range was formed by compression and crustal foreshortening, which produced folding and thrust faulting. Venusian mountain ranges are usually named after goddesses, but Maxwell Montes is named after the British physicist James Clerk Maxwell, a pioneer of electromagnetic radiation.

VENUS GUINEVERE PLANITIA

ISHTAR TERRA

Sacajawea Patera TYPE

Caldera

Under 500 million years AGE

DIAMETER

145 miles

BETA REGIO

Sachs Patera TYPE

Caldera

Under 500 million years LENGTH

40 miles (65 km)

(233 km)

Sacajawea Patera is an elliptically shaped volcanic caldera on Lakshmi Planum. It is thought to have formed when a large underground chamber was drained of magma and then collapsed. The resulting caldera then sagged. The depression is about 0.75 miles (1.2 km) deep and is enclosed by a zone of concentric troughs and scarps that extend up to 60 miles (100 km) in length and are 0.3–2.5 miles (0.5–4 km) apart. They are thought to have formed as the caldera sagged. Sacajawea was a Shoshoni Indian woman, born in 1786, who worked as an interpreter.

BETA REGIO

Beta Regio

AGE

Devana Chasma TYPE

Volcanic highland

TYPE

Fault

AGE

Under 500 million years

Under 500 million years

LENGTH 1,781 miles (2,869 km)

LENGTH 2,860 miles (4,600 km)

Sachs Patera is about 420 ft (130 m) deep and is surrounded by scarps spaced 1–3 miles (2–5 km) apart. A second, separately produced arcshaped set of scarps lies to the north (top in the image below) of the main caldera. Solidified lava flows extend 6–16 miles (10–25 km) to the north and northwest of those scarps.

Beta Regio is a large highland region dominated by Rhea Mons and Theia Mons. Rhea, which lies 500 miles (800 km) to the north of Thea, was originally thought to be a volcano, but Magellan data revealed it to be an uplifted massif cut through by a rift valley, the Devana Chasma (right). Theia Mons is a volcano superimposed onto the rift.

SCARPS AROUND SACHS PATERA

RHEA AND THEIA MONS

SAG-CALDERA

Bright linear scarps extend out from Sacajawea Patera’s eastern edge.

119

AGE

Devana Chasma is a large fault that cuts through Beta Regio (left). This major rift valley extends in a north–south direction and was produced as the planet’s crust pulled apart and the surface sank to form LANDSLIDE a valley floor with steep sides. It is similar to the Great Rift Valley on Earth (see p.130). Devana Chasma slices through Rhea Mons and Theia Mons. The fault is over 1.2 miles (2 km) deep and about 50 miles (80 km) wide near Rhea Mons. Elsewhere it is broader, as much as 150 miles (240 km) wide. To the south of Theia Mons, it continues to the highland region Phoebe Regio and reaches depths of 3.7 miles (6 km). Faults and grabens cut through and fan out from parts of the rift valley.

EISTLA REGIO

Gula Mons TYPE

Shield volcano

Under 500 million years AGE

HEIGHT

WESTERN EISTLA REGIO

Lava flows extending for hundreds of miles fill the foreground of this image. In the distance, Gula Mons (left) and Sif Mons (right) rise above the plain, about 450 miles (730 km) apart.

EISTLA REGIO

Eistla Regio TYPE

Volcanic highland

Under 500 million years AGE

Eistla Regio is one of Venus’s smaller upland areas, which are located in the lower basin land separating the major highland areas. Eistla Regio lies in the equatorial region to the west of the major highland, Aphrodite Terra. It is a series of broad crustal rises, each of which is several thousand miles across. The landscape was seen for the first time in the 1980s, when data collected by the Pioneer Venus Orbiter was used to produce the first accurate

broad volcanic rises and rift zones. An unusual type of volcanic dome, unique to Venus, is found within Eistla Regio. The domes are circular, flattopped mounds of lava and so are often referred to as pancake domes. It is believed that when the lava erupted through the surface, it was highly viscous and so didn’t flow freely. Cracks and pits in the domes are caused by cooling and withdrawal of lava.

Gula Mons is the larger of the two volcanoes that dominate the highland rise of western Eistla Regio (left). At its widest, it measures about 250 miles (400 km) across. This shield volcano is encircled by hundreds of miles of lava flows. It does not have a caldera at its summit, but a fracture line 93 miles (150 km) long. The volcano is also at the center of an array of crustal fractures. A particularly prominent one, Guor Linear, is a rift system that extends for at least 600 miles (1,000 km) from the southeast flank.

PANCAKE DOMES

The two large, flat pancake domes are each about 37 miles (60 km) across and less than 0.6 miles (1 km) in height.

SOUTHWEST SLOPES OF SUMMIT

TH E SO LA R S Y S TE M

LENGTH 4,977 miles (8,015 km)

topographic map of Venus. Prominent features, such as the volcanoes Sif Mons and Gula Mons (right) and their lava flows, were clearly visible in the west of the region. Eistla Regio was also the first of the equatorial highlands imaged in the 1990s by Magellan, which revealed more detail of the

2 miles (3 km)

120

VENUS ATLA REGIO

Sapas Mons TYPE

Shield volcano

Under 500 million years AGE

HEIGHT

1 mile (1.5 km)

TH E S OL A R SY ST E M

Rising 1 mile (1.5 km) above the surrounding terrain and with a diameter of about 135 miles (217 km), Sapas Mons is one of Venus’s shield volcanoes. These are shaped like a shield or inverted plate, with a broad base and gently sloping sides, and are like those found on Earth’s Hawaiian Islands. Sapas Mons is located in the Atla Regio, a broad volcanic rise just north of Venus’s equator with an average elevation of 2 miles (3 km). The region is believed to have formed as a result of large volumes of molten rock welling up from the planet’s interior. It is home to some particularly large shield volcanoes, which are linked by complex systems of fractures. These include Ozza

SAPAS SUMMIT

The bright feature in the foreground is the summit of Sapas Mons, and Maat Mons is the volcano rising up behind it. The vertical scale has been exaggerated to emphasize the surface features.

CRATER ON EASTERN FLANK

Bright lava flows from Sapas Mons have stopped short of an impact crater on the volcano’s eastern side. The flows, which are tens of miles long, cover some of the ejecta and therefore are younger than the crater.

Mons, which is 4 miles (6 km) high, and the largest Venusian volcano, Maat Mons, which is 5 miles (8 km) high. Sapas Mons is covered in lava flows and grew in size as the layers of lava accumulated. The flows near the summit appear bright in Magellan radar images, suggesting that these are rougher than the dark flows farther

down the volcano’s flanks. The flows commonly overlap, and many originate from the flanks rather than the summit. The summit has two mesas with flat to slightly convex tops. Nearby are groups of pits up to 0.6 miles (1 km) wide that are believed to have formed when underground chambers of magma drained away and the surface collapsed. The shield volcanoes are mainly named after goddesses: Sapas was a Phoenician goddess; Ozza, a Persian one; and Maat, an Egyptian.

DOUBLE SUMMIT

In this Magellan image of Sapas Mons taken from directly overhead, the two flat-topped mesas, which give the volcano the appearance of a double summit, appear dark against the bright lava flows. The area shown covers about 400 miles (650 km) from top to bottom.

VENUS

121

APHRODITE TERRA

LINEAR RIDGES

Miralaidji Corona

Ridges 20–40 miles (30–60 km) long lie along a northern slope of Ovda Regio. Dark lava, or possibly windblown dirt, fills the spaces between the ridges.

TYPE

Corona

Under 500 million years AGE

DIAMETER

186 miles

(300 km)

APHRODITE TERRA

Ovda Regio TYPE

Highland terrain

Under 500 million years AGE

DIAMETER

3,279 miles

(5,280 km)

Ovda Regio is a highland area in Venus’s equatorial region. It forms the western part of Aphrodite Terra, Venus’s most extensive highland system, which rises 2 miles (3 km) above the mean surface level. Ovda Regio is one of a handful of highland regions on Venus that displays a type of complex ridge terrain known as tessera, a form of terrain, that was first identified in images taken by Veneras

15 and 16. Tesserae are raised plateaushaped regions with chaotic and complex patterns of crisscrossing lines. In places, the planet’s crust has been fractured into mile-sized blocks. Elsewhere there are folds, faults, and belts of ridges and grooves hundreds of miles long. These are best seen along Ovda Regio’s boundaries, where curving ridges and troughs have developed. There is also evidence that volcanic activity has played its part in the shaping of HIGHLANDS AND LOWLANDS

Tessera ridges run between the Ovda Regio highland (right) and lowland lava flows (left). Some of the highland depressions have been partially filled by smooth material.

RADIAL FAULTING

APHRODITE TERRA

APHRODITE TERRA

TYPE

Fault

TYPE

Lada Terra

Corona

Under 500 million years

Under 500 million years

LENGTH 1,291 miles (2,077 km)

(2,600 km)

AGE

AGE

DIAMETER

1,614 miles

Artemis is more than twice as big as the next largest corona on Venus, Heng-o. A nearly circular trough, Artemis Chasma, which has a raised rim, marks its boundary. Within it are complex systems of fractures, volcanic flows, and small volcanoes. Artemis, like other coronae, could have been formed by hot material welling up under the surface. But its large size and the surrounding trough mean that other forces, such as the pulling apart of the crust and surface, were involved.

TYPE

Highland terrain

Under 500 million years AGE

LENGTH 5,350 miles (8,615 km)

Lada is the second largest of three highland regions on Venus. It is in the south polar region of the planet, largely south of latitude 50°S, and comparatively little is known about it. Lada Terra includes some typical tessera terrain of crisscrossing troughs and ridges.Volcanic activity has also affected the area. Lada includes three large coronae (blisterlike features), called

Part of a 745-mile(1,200-km-) long channel, carved through Lada Terra by high-temperature, very fluid lava, runs from west to east across the center of this image.

Quetzalpetlatl, Eithinoha, and Otygen. Lava has flowed over and cut through the northern part of the region. All three terras on Venus are named after goddesses of love: Aphrodite is named after the Greek goddess; Ishtar (see p.118), the Babylonian goddess; and Lada, the Slavic goddess.

TROUGHS

In this view along the Dali Chasma, part of the raised rim of the 600-mile(1,000-km-) wide Latona Corona is visible on the left.

RIDGE BELT

Bright and dark lava flows from the Ammavaru Volcano, which is 200 miles (300 km) to the left of this image, cut across a ridge belt to form a massive pool of lava. ARTEMIS CORONA AND ARTEMIS CHASMA

TH E SO LA R S Y S TE M

The Dali Chasma lies in western Aphrodite Terra. It is a system of canyons and deep troughs coupled with high mountains that makes a broad, curving cut through more than 1,200 miles (2,000 km) of the planet’s surface. Along with the Diana Chasma system, it connects the Ovda and Thetis highland regions with the large volcanoes at Atla Regio. The mountain ranges associated with the canyons rise for 2–2.5 miles (3–4 km) above the surrounding terrain. The canyons are 1.2–2.5 miles (2–3 km) deep.

LAVA CHANNEL

LADA TERRA

Artemis Corona

Dali Chasma

this landscape. Magma, which may have welled up from the planet’s interior, has flowed across part of the region, and ridges formed by compression have filled with lava. Ovda Regio is named after a Marijian (Russian) forest goddess.

This large volcanic feature was formed by a plume of magma rising under the Venusian surface. The magma partially melted the crustal rock, which was raised up above the surrounding land to produce the corona, a blisterlike formation with radial faulting. The coronae on Venus range in size from about 30 to 1,600 miles (50 to 2,600 km) across and are circular to elongate in shape. They are named after fertility goddesses. Miralaidji is an Aboriginal fertility goddess.

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IMPACT CRATERS Meteorite impact craters on Venus range in size from 4 miles (7 km) to 168 miles (270 km) across. The largest are multiple-ringed, those of intermediate size have central peaks, and the smaller ones have smooth floors. The smallest of all—simple, bowl-like craters that are common on the Moon and Mars—are scarce on Venus, because the thick atmosphere filters out the small asteroids that would create them. Venusian craters are young and in many cases in pristine condition. The last volcanic resurfacing of Venus could have occurred as CUNITZ CRATER recently as 500 million years ago, so its craters must have mostly This typical impact crater has a dark basin 30 miles (48 km) formed since then, and there has been little geological activity or wide, with mountainous weathering to affect them. Individual craters on Venus are named central peaks and a bright after women of note or are given female first names. ejecta blanket around it. ISHTAR TERRA

ISHTAR TERRA

Wanda Crater TYPE

GUINEVERE PLANITIA

Cleopatra Crater

Central-peak crater

TYPE

Under 500 million years

Under 500 million years

DIAMETER 21.6 km (13.4 miles)

(105 km)

AGE

Wanda Crater is in the northern part of the Akna Montes mountain range. It was mapped first in 1984, by the Venera 15 and 16 missions, and Magellan studied it again a few years later. The crater has a large, rugged peak in the center of its smooth, lavaflooded floor. About one-third of all Venusian craters have such peaks. Material from the mountain ridges seems to have collapsed into the crater’s western edge. CENTRAL PEAK

Jeanne Crater

Double-ring crater

TYPE

DIAMETER

AGE

65 miles

Cleopatra Crater is named after the legendary Egyptian queen. It is located on Maxwell Montes,Venus’s highest mountain range, and stands out as a smooth, eyelike feature against the rough mountainous terrain. Cleopatra was imaged by the Venera 15 and 16 spacecraft and the Arecibo radio telescope in the mid-1980s. It was one of several circular features that resembled both an impact crater and a volcanic feature. The data of the time revealed a feature of apparently great depth, without the rim deposits typical of impact craters. As a result, Cleopatra was classified as a volcanic caldera. However, high-resolution

DIAMETER

12 miles

(19.4 km)

MYSTERY CRATER

The dark inner basin, the rim, and the surrounding ejecta revealed in this Magellan image from 1990 convinced astronomers that Cleopatra is an impact crater.

images from Magellan revealed an inner basin and rough ejecta deposits, providing conclusive proof that Cleopatra is an impact crater.

BETA REGIO

An asteroid traveling from the southwest smashed obliquely into the Guinevere Planitia and created Jeanne Crater. Ejecta pushed out of the impact basin produced a distinctive triangular shape. Lobes formed to the northwest of the crater as molten material produced by the impact flowed downhill. TRIANGULAR EJECTA

APHRODITE TERRA

Balch Crater TYPE

Riley Crater Central-peak crater

TYPE

Under 500 million years DIAMETER

AGE

25 miles (40 km)

Most impact craters on Venus have remained unchanged since they were formed and have sharply defined rims. However, a relatively small number have been modified by volcanic eruptions and other kinds of tectonic activity. Balch Crater is one of these. Its circular form was split in two as the land was wrenched apart during the formation of a deep rift valley. The rift, which is up to 12.4 miles (20 km) wide, created a division that runs from north to south through the crater’s center. The western half of the crater remains intact, but most of the eastern half was destroyed. A central peak and an ejecta blanket are visible in the western half. The crater was initially called Somerville, but is now named after American economist and Nobel laureate Emily Balch.

Central-peak crater

Under 500 million years

AGE

TH E S OL A R SY ST E M

Central-peak crater

Under 500 million years

AGE

DIAMETER

16 miles (25 km)

Riley Crater, named after 19thcentury botanist Margaretta Riley, is one of the few Venusian craters to have been precisely measured. Comparison of images from different angles shows that the 16-mile- (25km-) wide crater’s floor lies 1,880 ft (580 m) below the surrounding plain, the rim is 2,009 ft (620 m) above it, and the peak is 1,737 ft (536 m) high.

HALF CRATER

A rift valley separates most of the Balch Crater (left) from its smaller eastern part, just visible on the opposite side of the fault. The original central peak is the bright patch in the crater’s western part. OBLIQUE VIEW OF RILEY CRATER

VENUS THREE CRATERS

LAVINIA PLANITIA

APHRODITE TERRA

Saskia Crater

Mead Crater TYPE

Multi-ringed crater

TYPE

DIAMETER

AGE

168 miles

DIAMETER

23 miles

(37.1 km)

(270 km)

Mead is the largest impact crater on Venus—although compared to craters on the Moon and Mercury, it is not very large. Mead is a multiple-ringed crater whose inner ring is the rim of the crater basin. This encloses a smooth, flat floor, which hides a possible central peak. The crater floor was flooded at the time of impact as a result of impact melt or by volcanic lava being released from below the surface. This explains why a crater of Mead’s size is so shallow; there is a drop of only about 0.6 miles (1 km) between the crater rim and the crater center.

Central-peak crater

Under 500 million years

Under 500 million years AGE

Saskia lies at the lower left of this 300mile- (500-km-) wide segment of Lavinia Planitia. Above it are the Danilova and Aglaonice craters.

Saskia is a middle-sized crater, and its ejecta pattern is typical for its size. The ejecta blanket extends all the way around the crater’s basin, suggesting that the impacting body smashed into the surface at a high angle. The crater has central peaks, formed as the planet’s surface recoiled after being

pushed down by the energy released during the impact. The original crater rim has collapsed and formed terraced walls. The incoming object must have been about 1.6 miles (2.5 km) across to produce a crater of this size. Images of Saskia and other craters, such as the similarly sized Danilova (30.3 miles/

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48.8 km wide) and Aglaonice (39.6 miles/63.7 km wide), which lie within a few hundred miles of Saskia, have been produced from radar data collected by Magellan. Raw radar images (such as the one above) do not show features as they would appear to the naked eye. Instead, brightness varies according to the smoothness of the surface— rough areas appear light, while smooth ones look dark.

LARGEST CRATER

Mead has two distinct rings. Ejecta lies between them and beyond the outer ring. The vertical bands running through the picture are a result of image processing.

SASKIA CRATER IN 3-D

The color in this 3-D perspective view of Saskia is based on the color images of the Venusian surface recorded by the Venera 13 and 14 spacecraft.

LAVINIA PLANITIA

LADA TERRA

Stein Crater Field TYPE

Alcott Crater

Crater field

TYPE

Degraded crater

AGE

Under 500 million years

Under 500 million years

DIAMETER 8.7 miles (14 km), 6.8 miles (11 km), and 5.6 miles (9 km)

DIAMETER

CRATER AND OUTFLOW

AINO PLANITIA

A 372-mile- (600-km-) long, radar-bright flow of once-molten debris stretches to the east of Addams Crater.

Addams Crater TYPE

Central-peak crater

Under 500 million years AGE

DIAMETER

54 miles ( 87 km)

The large, circular Addams Crater measures almost 55 miles (90 km) across, but it is its long tail that makes this crater unusual. An asteroid hit the ground from the northwest and created a crater basin with an ejecta blanket stretching out beyond about three-quarters of the crater rim. Additionally, impact-melt ejecta and lava extend out from about a third of the rim, creating a mermaid-style tail

to the east. The molten material flowed downhill for about 370 miles (600 km) from the impact site. The Magellan spacecraft found this area to be radar bright—that is, it bounced back a large portion of the radio waves that Magellan transmitted to it, which suggests it has a rugged surface. Venus’s high surface temperature of about 867°F (464°C) allows ejecta to remain molten for a longer time than if it were on Earth. However, once the material cools below about 1,800°F (1,000°C) it becomes so viscous it stops flowing. The crater is named after the American social reformer Jane Addams.

41 miles (66 km)

Alcott is one of the few craters on Venus that have been modified by volcanic activity not associated with the crater’s production. Many craters have floors flooded with lava that came up through the surface as the crater basin was formed. In Alcott’s case, lava erupted elsewhere and then flowed over the crater. About half of the crater’s rim is still visible, along with ejecta from the original impact lying to the south and east. A channel where lava once flowed touches the southwest edge of the crater.

MODIFIED BY LAVA

TH E S O LA R S Y S TE M

Small asteroids heading for Venus’s surface can be broken up by the planet’s dense atmosphere. The resulting fragments continue heading toward the surface, striking it simultaneously within a relatively small area to form a crater field. The Stein field consists of three small craters. The two smallest ones overlap. Material ejected by all three craters extends mainly to the northeast, suggesting that the fragments struck from the southwest. Material melted by the impacts has formed flow deposits, also lying STEIN TRIPLETS to the northeast.

AGE

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EARTH

EARTH EARTH IS THE THIRD-CLOSEST PLANET

to the Sun. The largest of the four rocky planets, it formed 56–57 Life in the universe approximately 4.56 billion years ago. Earth’s 64–67 Celestial cycles internal structure is similar to that of its planetary 68–69 Planetary motion neighbors, but it is unique in the solar system 74–75 Lights in the sky in that it has abundant liquid water at its 103 The rocky planets surface, an oxygen-rich atmosphere, and is known to support life. Earth’s surface is in a state of constant dynamic change as a result of processes occurring within its interior and in its oceans and atmosphere. 38–39 Gravity, motion, and orbits

ORBIT Earth orbits the Sun at an average speed of 67,000 mph (108,000 km/h), in a counterclockwise direction when viewed from above its North Pole. Like the other planets, Earth orbits the Sun along an elliptical path. As a result, about 7 percent more solar radiation currently reaches Earth’s surface in January than in July. The plane of Earth’s orbit around the Sun is called the ecliptic plane. Earth’s spin axis is not perpendicular to this plane but is tilted at an angle of 23.5°. The eccentricity of Earth’s elliptical orbit around the Sun (the degree to which it varies from a perfect circle) changes over a cycle of about 100,000 SPIN AND ORBIT years, and its axial tilt varies over a 42,000Earth is about 3 percent year cycle. Combined with a third cycle— closer to the Sun at perihelion (in January) a wobble in the direction in which the spin than at aphelion (in axis points in space, called precession (see July). Its axial tilt p.64)—these variations are believed to play a combined with its part in causing long-term cycles in Earth’s elliptical orbit gives rise climate, such as ice ages. to seasons (see p.65). NORTHERN SUMMER SOLSTICE

axis tilts from the vertical by 23.5°

NORTHERN SPRING EQUINOX

APHELION 94.5 million miles (152.1 million km)

PERIHELION 91.4 million miles (147.1 million km)

Sun

NORTHERN FALL EQUINOX

NORTHERN WINTER SOLSTICE Earth orbits the Sun in 365.26 days

STRUCTURE TH E S OL A R SY ST E M

Earth spins on its axis once every 23.93 hours

Earth’s rotation causes its equatorial regions to bulge out slightly, by about 13 miles (21 km) compared to the poles. Internally, Earth has three main layers. The central core has a diameter of about 4,350 miles (7,000 km) and is made mainly of iron with a small amount of nickel. It has a central solid part, which has a temperature of about 8,500°F (4,700°C), and an outer liquid part. Surrounding the core is the mantle, which contains rocks rich in magnesium and iron and is about 1,700 miles (2,800 km) deep. Earth’s crust consists of many different types of rocks and minerals, predominantly silicates, and is differentiated into continental crust and a thinner oceanic crust.

solid, rocky crust

mantle of solid silicate rock

molten iron-nickel outer core

solid iron-nickel inner core

EARTH INTERIOR

At Earth’s center is a hot dense core. Surrounding the core are the mantle and the thin, rocky outer crust, which supports Earth’s biosphere, with its oceans, atmosphere, plants, and animals.

EARTH WATER WORLD

Viewed from space, what clearly makes Earth unique is the abundance of surface water— in the oceans, lakes, atmosphere, and polar ice caps. The presence of surface water has been a key factor in the development of life on Earth.

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EARTH PROFILE

AVERAGE DISTANCE FROM THE SUN

ROTATION PERIOD

93.0 million miles (149.6 million km)

23.93 hours

AVERAGE SURFACE TEMPERATURE

ORBITAL PERIOD (LENGTH OF YEAR)

59°F (15°C)

365.26 days

DIAMETER

7,926 miles (12,756 km)

VOLUME (EARTH = 1)

1

NUMBER OF MOONS

1

MASS (EARTH = 1)

1

GRAVITY AT EQUATOR (EARTH = 1)

1

MAGNETIC FIELD Earth has a substantial magnetic field, which is thought to be caused by a swirling motion of its liquid metal outer core. This motion is driven by a combination of Earth’s rotation and convection currents within the outer core. The magnetic field behaves as though a large bar magnet were present within the Earth, tilted at an angle to its axis of rotation. The lines of the magnetic field converge at two points on Earth’s surface called the north and south magnetic poles. The location of these points slowly changes over time. Currently, the north magnetic pole is north of Canada in the Arctic Ocean, while the south magnetic pole is north of JAMES VAN ALLEN eastern Antarctica, in the James Van Allen (1914–2006) is Southern Ocean. The an American physicist who, in magnetic field extends into the 1950s, designed and built space, forming a protective instruments for American satellites. blanket around the planet by In 1958, a Van Allen-designed deflecting high-speed streams instrument carried by the first US of charged particles that flow satellite, Explorer 1, detected two toward Earth in the solar wind large, doughnut-shaped belts of radiation around Earth, which carry (see p.107). A few of the trapped charged particles. The belts particles escape deflection and are named after Van Allen. become trapped within two regions surrounding Earth called the Van Allen radiation belts (see panel, right). Studies of iron-rich minerals in Earth’s crust have shown that at variable time intervals (from less than 100,000 to millions of years) Earth’s north and south magnetic poles switch. magnetic axis magnetic equatorial plane

direction of magnetic force lines

bow shock

EARTH’S MAGNETOSPHERE

The imaginary surface at which Earth’s magnetic field first deflects the solar wind is called the bow shock. Behind it is a region of space dominated by the magnetic field, in the sense that the field prevents solar wind particles from entering. Despite its elongated shape, this region is called the magnetosphere.

magnetosphere tail Van Allen belts

TH E SO LA R S Y S TE M

solar wind

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EARTH

THERMOSPHERE

HEIGHT ABOVE SEA LEVEL

The thermosphere extends to over 375 miles (600 km) above the Earth’s surface. Temperature rises rapidly in the lower thermosphere due to absorption of solar energy and then increases gradually with altitude, reaching as high as 3,100°F (1,700°C).

130 km 81 miles 120 km 75 miles 110 km 68 miles aurora

meteor burning up in the atmosphere

100 km 62 miles 90 km 56 miles 80 km 50 miles

MESOSPHERE

This layer extends up to about 50 miles (80 km). Temperatures fall through the mesosphere to as low as –135°F (–93°C).

ice crystals on meteoric dust

70 km 43 miles 60 km 37 miles

ozone layer absorbs harmful radiation from the Sun

STRATOSPHERE

The stratosphere is a calm layer stretching up to about 30 miles (50 km) above sea level. The temperature rises to 27°F (–3°C) at the top of this layer.

50 km 31 miles 40 km 25 miles 30 km 19 miles 20 km 12 miles

TROPOSPHERE

This layer extends to 5 miles (8 km) above the poles and 10 miles (16 km) above the equator. It contains 75 percent of the total mass of the atmosphere. Temperatures fall to as low as –62°F (–52°C) at the top. nitrogen 78.1%

10 km 6 miles sea level

ATMOSPHERE AND WEATHER Earth is surrounded by the atmosphere, a layer of gases many hundreds of miles thick. This atmosphere is thought to have arisen partly from gases spewed out by ancient volcanoes, although its oxygen content—so vital to most forms of life—was created mainly by plants. Through the effects of gravity, the atmosphere is densest at Earth’s surface and rapidly thins with altitude. With increasing altitude, there are also changes in temperature and a progressive drop in atmospheric pressure. For example, at a height of 19 miles (30 km), the pressure is just 1 percent that at sea level. Within the lowest layer of the atmosphere, the troposphere, continual changes occur in temperature, air flow (wind), humidity, and precipitation, known as weather. The basic cause of weather is the fact that Earth absorbs more of the Sun’s heat at the equator than the poles. This produces variations in atmospheric pressure, which create wind systems. The winds drive ocean currents and cause masses of air with different temperatures and moisture content to circulate over the planet’s surface. Earth’s rotation plays a part in causing this atmospheric circulation because of the Coriolis effect (below). ATMOSPHERIC LAYERS

The four main layers in Earth’s atmosphere are distinguished by different temperature characteristics. No boundary exists at the top of the atmosphere. Its upper regions progressively thin out and merge with space.

all weather occurs in the lowest level of the atmosphere

initial direction of moving air deflection to right (Northern Hemisphere)

direction of spin

THE CORIOLIS EFFECT

The Coriolis effect causes deflections of air moving across Earth’s surface. It is a consequence of the fact that objects at different latitudes move at different speeds around Earth’s spin axis.

argon and trace gases 1% deflection to left (Southern Hemisphere)

COMPOSITION OF ATMOSPHERE

oxygen 20.9%

Nitrogen and oxygen make up 99 percent of dry air by volume. About 0.9 percent is argon, and the rest consists of tiny amounts of other gases. The atmosphere also contains variable amounts (up to 4 percent) of water vapor.

destructive boundary, where tectonic plates converge

plate dragged along by convection current

circular motion of convection current plate in collision descends into mantle

upp er ma nt le low er ma nt le

PLATE TECTONICS

TH E S O LA R S YS TEM

constructive boundary, where plates diverge and new crust is created

Earth’s crust and the top part of its mantle are joined in a structure called the lithosphere. This is broken up into several solid structures called plates, which “float” on underlying semi-molten regions of the mantle and move relative to each other. Most plates carry both oceanic crust and some thicker continental crust, although a few carry only oceanic crust. The scientific theory concerning the motions of these plates is called plate tectonics, and the phenomena associated with the movements are called tectonic features. Most tectonic features, which include ocean ridges, deep sea trenches, high mountain ranges, and volcanoes, result from processes occurring at plate boundaries. Their nature depends on the type of crust on either side of the boundary and whether the plates are moving toward or away from each other. Tectonic features TECTONIC PLATES Earth’s surface is broken occurring away from plate boundaries include into seven large plates, such volcanic island chains, such as the Hawaiian as the Eurasian plate, and islands. These are caused by magma (molten rock) many smaller ones, such as the upwelling from “hot spots” in the mantle, causing a Indian plate. Each continent is series of volcanoes to form on the overlying plate. embedded in one or more plates.

mantle plume rises from lower mantle

ou ter

co re

lithospheric tectonic plate

MOVING PLATES

Earth’s plates move relative to each other as a result of convection currents within the mantle. The currents cause parts of the mantle to rise, move sideways, and then sink again, dragging the plates along as they do so. North American Plate Eurasian Plate Pacific Plate Plate boundary Indian Plate Australian Plate

EARTH

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SURFACE FEATURES

SANDY DESERT

Deserts cover about 20 percent of Earth’s land surface, but only a small proportion are occupied by sand dunes, like these in the Sahara Desert.

From space, the flatter areas of Earth’s land surface (apart from the areas dominated by ice) appear either dark green or various shades of yellow-brown. The green areas are forests and grasslands, which comprise a major component of Earth’s biosphere (the planet’s life-sustaining regions). The yellowbrown areas are mainly deserts, which have been created over long periods by various weathering and erosional processes. Like the other rocky planets, Earth has suffered many thousands of meteorite impacts over its history (see p.103). But because Earth’s surface is so dynamic, the evidence for most of these impacts has disappeared, removed by erosion or covered up by depositional processes.

WATER

RAINFOREST

Forests cover 30 percent of Earth’s land surface and range from the cold, dark boreal forest of the far north to the dense rainforests of the humid tropics.

Water is a dominant feature of Earth’s surface. Overall, about 97 percent of the water is in oceans (which cover 75 percent of the surface), 2 percent is in ice sheets and glaciers, less than 1 percent is in ground water (underground and in rocks), and the rest is in rivers, lakes, and the atmosphere. The presence of liquid water has been key to the development of life on Earth, and the heat capacity of the oceans has been important in keeping the planet’s temperature relatively stable. Liquid water is also responsible for most of the erosion and weathering of Earth’s continents, a process unique in the solar system, although it is believed to have occurred on Mars in the past.

KINGDOMS OF LIFE Biologists use various systems for classifying living organisms, but the most widely used is the five-kingdom system. This classifies organisms mainly on the basis of their cell structure and method of obtaining nutrients and energy. However, not all scientists accept this system as satisfactory, and some have proposed switching to an eight-kingdom system or one with 30 kingdoms grouped into three superkingdoms. ANIMALS

VERTEBRATE

Animals are multicellular organisms that contain muscles or other contractile structures allowing some method of movement. They acquire nutrients, and so gain energy, by ingesting food. Many animals, including mammals, are vertebrates (they possess a backbone), but a far larger number are invertebrates (without a backbone). PLANTS

clouds carry water inland loss of water from plants by transpiration

water evaporates from sea and condenses to form clouds

frozen water accumulates in glaciers water seeps into ground and flows to sea

TOADSTOOL water returns to sea via rivers and streams

Monerans are the simplest, smallest, most primitive, and most abundant organisms on Earth. The two main groups are bacteria and blue-green algae (cyanobacteria). Monerans are single-celled but their cells contain no distinct nucleus. Most reproduce by splitting in two.

MYCOBACTERIUM

THE GLOBAL WATER CYCLE

Earth’s water is in a state of continuous movement, passing between the oceans and lakes, the atmosphere, and the land in a cycle of connected processes.

LIFE ON EARTH Evidence in ancient rocks points to the presence of simple, bacteria-like organisms on Earth some 3.8 billion years ago. However, the prevailing scientific view is that life started on Earth long before that, as a result of complex chemical reactions in the oceans or atmosphere. These reactions eventually led to the appearance of a self-replicating and self-repairing molecule, a precursor of DNA (deoxyribonucleic acid). Once life, in this rudimentary form, had started, processes such as mutation and natural selection inevitably led, over the vast expanses of geological time, to a collection of life forms of increasing diversity and complexity. Life spread from the seas to the land and to every corner of the planet. Currently, Earth is teeming with life in astonishing abundance and diversity.

TH E S OL A R S Y S TE M

PARAMECIUM

Protists are microscopic, mainly single-celled organisms whose cells contain nuclei. Some gain energy from sunlight, others ingest food like animals. MONERANS

water returns to land as snow

loss of water from lakes by evaporation

FLOWERING PLANT

Fungi acquire nutrients by absorption from other living organisms or dead and decaying organic material. They have no means of locomotion. They range from yeasts (microscopic unicellular organisms) to multicellular forms with large fruiting bodies, such as mushrooms. PROTISTS

ice melts to form meltwater streams

water returns to land as rain

Plants are multicellular organisms that obtain energy from sunlight through the process of photosynthesis. Their cells contain special pigments for absorbing light energy and are enclosed by cell walls made of cellulose. FUNGI

water flows downhill in rivers

ISLAND VORTICES

These twisting cloud patterns are caused as low-level winds blow over the Cape Verde islands (seen in the upper right of this image), in the Atlantic Ocean off the coast of West Africa. They are seen here in a natural-color image from the MODIS instrument on board NASA’s Earthwatching Terra satellite. Such repeating patterns of swirls are technically termed von Kármán vortex streets.

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TECTONIC FEATURES Most of Earth’s tectonic features are associated with plate boundaries. At constructive (or divergent) boundaries, plates move apart and new crust is added. Examples are mid-ocean ridges and the East African Rift. At destructive (or convergent) boundaries, two plates push against each other, producing a range of features, depending on the nature of the crust on each plate. THE SAN ANDREAS FAULT This fault in California, known for Many plate boundaries are associated producing earthquakes, marks a with an increased frequency of transform boundary where two volcanism, earthquakes, or both. plates push past each other.

AFRICA east and ASIA southwest

East African Rift Extending from Mozambique northward through East Africa, the Red Sea, and into Lebanon LOCATION

TYPE

Series of rift faults

5,300 miles (8,500 km) LENGTH

The East African Rift provides an example of the geological process of rifting—the stretching and tearing apart of a section of continental crust by a plume of hot magma pushing up underneath it. Rifting is associated OL DOINYO LENGAI

This active volcano in northern Tanzania sits in the middle of the east African part of the East African Rift.

with the development of a constructive plate boundary, which is formed as ascending magma creates new crust and pushes the plates on either side of the rift apart. The main section of the East African Rift runs (in two branches) through eastern Africa. Over tens of millions of years, rifting in this region has caused extensive faulting, the collapse of large chunks of crust, and associated features such as volcanism and a series of lakes in the subsided sections. As rifting continues, it is anticipated that a large area of eastern Africa will eventually split off as a separate island. A northern arm of the rift valley runs up the Red Sea and eventually reaches Lebanon, in the north. This coincides with a divergent boundary that is pushing Arabia away from Africa.

THE NORTHERN RED SEA

The Gulf of Aqaba (center right), a branch of the Red Sea, forms part of the northern arm of the East African Rift. The Gulf of Suez (center) is a side branch of the rift.

ATLANTIC OCEAN

Mid-Atlantic Ridge LOCATION Extending from the Arctic Ocean to the Southern Ocean TYPE Slow-spreading mid-ocean ridge LENGTH 10,000 miles (16,000 km)

BLACK SMOKERS

TH E S O LA R S YS TEM

Hydrothermal vents are underwater geysers located near mid-ocean ridges. The hot water spewed out by some vents, called “black smokers,” is discolored by the dark mineral iron sulfide.

The Mid-Atlantic Ridge is the longest mountain chain on Earth and one of its most active volcanic regions, albeit mainly underwater. The ridge sits on top of the MidAtlantic Rise, a bulge that runs the length of the Atlantic Ocean floor. Both rise and ridge coincide with plate boundaries that divide the North and South American plates, on the west, from the Eurasian and African plates, on the east. These are constructive plate boundaries, where new ocean crust is formed by magma upwelling from Earth’s mantle. As this crust forms, the plates on either side are pushed away from the ridge at a rate of 0.4–4 in (1–10 cm) a year, widening the Atlantic

basin. The discovery in the 1960s of this spreading of the Atlantic sea floor— evidenced by the fact that crustal material near the ridge is younger than that farther away—led to general acceptance of the theory of continental drift. The ridge is a site of extensive earthquake activity and volcanism, along with many seamounts (isolated underwater mountains). Where the volcanoes break the ocean surface, they have formed islands such as Iceland and the Azores.

SURTSEY

Between 1963 and 1967, a massive and dramatic submarine eruption, from a section of the Mid-Atlantic Ridge to the south of Iceland, produced the new island of Surtsey.

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FIERY ARENAL

Arenal is one of the most active volcanoes in Costa Rica—a region where the small Cocos Plate is subducted under the neighboring Caribbean Plate.

OKMOK VOLCANO PACIFIC OCEAN

Pacific Ring of Fire Pacific Ocean rim, from Chile to New Zealand

LOCATION

TYPE Series of destructive boundaries LENGTH 20,000 miles (32,000 km)

The Ring of Fire is a huge arc of volcanic and seismic (earthquake) activity around the rim of the Pacific Ocean. It stretches from the western coasts of South America and North America, across the Aleutian Islands of Alaska, and down the eastern edge of Asia, to the northeast of Papua New Guinea, and finally to New Zealand. More than half of the world’s active volcanoes above sea level are part of the ring. The Ring of Fire results from the Pacific Plate and other

At the southwest corner of the Ring of Fire is New Zealand. Here, steam rises from the country’s tallest volcano, Ruapehu, between eruptions that occurred in 1995 and 1996.

The volcanic Aleutian Islands were created as the Pacific Plate was driven under the oceanic crust of the North American Plate. This volcano is on the island of Umnak.

large mountain ranges, interspersed with volcanoes, along much of the western coast of the Americas. These include the Cascade Range in Washington State, home of the active volcano Mount St. Helens, and the Andes in South America, Earth’s longest and most active land mountain range.

MOUNT FUJI

In the northwest Pacific, the subduction of the Pacific Plate under the Eurasian Plate is responsible for creating the islands of Japan, the site of volcanoes such as Mount Fuji, which last erupted in 1707.

TH E S OL A R S Y S TE M

MOUNT RUAPEHU

smaller plates in the Pacific colliding with neighboring plates along a series of destructive plate boundaries. The main driving force for this activity is the creation of new crust by a large mid-ocean ridge in the eastern Pacific (the East Pacific Rise). Here, new material is continually added to the Pacific and Nazca plates, and to the small Cocos Plate, forcing them toward the edges of the Pacific. Across much of its northern and western edges, the oceanic crust of the Pacific Plate is subducted (forced underneath) by the oceanic crust of other plates, forming deep-sea trenches. This predisposes these regions to earthquakes, and the subducted crust also melts deep down to create hot magma, which reaches the surface through volcanoes. The result has been the formation of many highly volcanic island arcs in these regions—examples being the Aleutian Islands, the Kurile Islands, the islands of Japan, and the Mariana Islands. On the eastern side of the Pacific, the situation is somewhat different. Here, parts of the Pacific, Nazca, and Cocos plates are being subducted below continental THE ANDES On the western edge crust. Deep-sea of South America, trenches have also formed here, subduction of the Nazca Plate under but instead of the South American island arcs, the Plate has created plate collisions the Andes, another have led to the highly active region. formation of

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EARTH ASIA south

Himalayas Running southeast from northern Pakistan and India across Nepal to Bhutan

LOCATION

Continent–continent collision TYPE

LENGTH 2,400 miles (3,800 km)

TH E S O LA R S Y S TE M

The Himalayas are the highest mountain range on Earth, as well as one of the youngest. If the Himalayas. Today, because the neighboring Karakoram Range is Himalayas are still rising, earthquakes included, the Himalayas contain and accompanying landslides remain Earth’s 14 highest mountain peaks, a common occurrence. each with an altitude of over 5 miles The mountains form a number of (8 km), including its highest mountain, distinct ranges. Traveling northward, Mount Everest. These peaks are still from the high plains being uplifted at the of the Ganges, the rate of some 20 in first of these are the (50 cm) per century Siwalik Hills, a line of by the continent– gravel deposits carried continent collision down from the high that originally mountains. Here, formed them. there are subtropical However, the forests of bamboo mountains are and other vegetation. weathered and Farther north are the eroded at almost the Lesser Himalayas, same rate, with the which rise to heights debris carried away of about 3,000 ft by great rivers, such EASTERN HIMALAYAS (5,000 m) and are as the Ganges and In this satellite view of an eastern traversed by Indus to the south. region of the Himalayas, which numerous deep The collision that extends into China, the snowgorges formed by brought about both covered high-altitude regions are swift-flowing streams. the Himalayas and clearly delineated. Farthest north are the the Tibetan Plateau Great Himalayas, between 20,000 and to its north occurred between 50 and 29,000 ft (6,000 and 8,800 m) tall 30 million years ago when tectonic and containing the highest peaks. plate movements caused India—at This region is heavily that time an island continent—to crash into Southeast Asia. For millions glaciated and contains lakes filled with of years before the collision, the floor glacial meltwater. of the ocean between India and Asia (called Tethys) was consumed by subduction under the Eurasian Plate. But once the ocean closed, first the continental margins between India MOUNT EVEREST At 29,035 ft (8,850 m), and Asia, and finally the continents Everest is the highest themselves, collided. The crust from peak on Earth. Satellite both was thickened, deformed, and studies show it is being metamorphosed, and parts of both uplifted by a fraction of continents and the floor of the Tethys an inch per year. Ocean were pushed up to form the

TIBETAN RANGE

The Kailas Range is a central region of the Himalayas, close to the border between Tibet and India. Here the mountains are viewed from the Tibetan Plateau, which is itself about 3 miles (5 km) above sea level.

GLACIAL LAKES

Many of the higher areas of the Himalayas are covered in glaciers and dotted with lakes dammed by glacial moraines. In the left foreground is the Tsho Rolpa Glacier Lake in northeast Nepal, which, at 15,092 ft (4,600 m), is one of the highest lakes on Earth.

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ROOF OF THE WORLD

In this photograph, taken from a NASA Space Shuttle, the snow-covered Himalayas, on the left, are bordered by Earth’s largest upland region, the vast and lake-spattered Tibetan Plateau.

TH E S O LA R S Y S TE M

134

FEATURES FORMED BY WATER Some of the most obvious and striking features of Earth’s surface are large bodies and flows of liquid water, such as oceans, seas, lakes, and rivers. In addition to these, there are landforms caused by the erosional or depositional power of liquid water, which include gorges, river valleys, and coastal features ranging from beaches to eroded headlands. Ice, too, has had a major impact on Earth’s appearance. Ice-formed features include existing GRAND CANYON bodies of ice, such as glaciers and ice-sheets, and Carved over millions of years by landforms, such as U-shaped valleys, sculpted by the Colorado River, the Grand the movement of past glaciers. Canyon is Earth’s largest gorge.

NORTH AMERICA northeast

BRAIDING

SOUTH AMERICA north

Great Lakes

Amazon River

Straddling the border of the US and Canada

Flows from the Peruvian Andes, across Brazil to the Atlantic Ocean

LOCATION

LOCATION

TYPE System of freshwater lakes

TYPE

94,480 square miles (244,767 square km)

LENGTH 3,995 miles (6,430 km)

AREA

River

NIAGARA FALLS

TH E S O LA R S YS TEM

The Great Lakes of North America are a system of five connected lakes that together form the largest body of fresh water on Earth. The lakes—named, from west to east, Superior, Michigan, Huron, Erie, and Ontario—contain 20 percent of Earth’s surface fresh water and drain a basin of approximately 289,900 square miles (751,100 square km). They are connected to each other by short rivers, a strait, and canals, and drain into the Atlantic Ocean via the St. Lawrence River. The Great Lakes began to form at the end of the last ice age when glacier-

The greatest drop in water level within the Great Lakes system is at Niagara Falls, between lakes Erie and Ontario. Here, the water plunges a spectacular 167 ft (51 m).

carved basins were filled with meltwater left by a retreating ice sheet. Originally, several of today’s lakes were united in one huge lake, but following post-glacial uplift in the region, they took on their present form about 10,000 years ago. The lake surfaces vary in height above sea level, from 600 ft (183 m) at Lake Superior to 246 ft (75 m) at Lake Ontario. Sprinkled across the lakes are thousands of islands, including Isle Royale on Lake Superior, which is itself big enough to hold several lakes.

The Amazon is the greatest river on Earth, whether measured by the area of the planet’s land surface that it drains or by the volume of water that it discharges every year. Overall, the Amazon accounts for nearly 20 percent of all river water discharged into Earth’s oceans. The source of the Amazon has been established as a headwater of the Apurímac River, a tributary of the MEETING THE ATLANTIC

The mouth of the Amazon occupies the whole top part of this image, which covers an area of tens of thousands of square miles. Rio Pará, the estuary of a separate major river, the Tocantins, can be seen at bottom.

Over its course, the Amazon frequently braids into channels, creating many temporary islands.

Ucayali, high in the Andes of southern Peru. The Ucayali flows north from this area, turns east, and joins another major tributary, the Marañón River, where it becomes the Amazon proper. The river then meanders for thousands of miles across the Amazon Basin, a vast flat area that contains Earth’s largest rainforest, merging with numerous tributaries along the way. Just east of Manaus, at its confluence with the Negro River, the Amazon is already 10 miles (16 km) wide, while still 1,000 miles (1,600 km) from the sea. At its mouth, the Amazon discharges into the Atlantic Ocean at the incredible rate of about 200 billion gallons of water (770 billion liters) every hour.

LAKES HURON AND SUPERIOR

MEANDERING TRIBUTARY

In this photograph taken from a NASA Space Shuttle, the largest lake, Superior, is on the right, and appears partly iced over. Lake Huron is on the left.

The Tigre is a tributary of the Amazon in Peru. Here, it meanders through the Peruvian rainforest, over 1,860 miles (3,000 km) from the Amazon’s mouth.

135 ASIA west

Caspian Sea On the borders of Azerbaijan, Iran, Kazakhstan, Russia, and Turkmenistan

LOCATION

TYPE

Saline inland sea

143,000 square miles (371,000 square km)

AREA

The Caspian Sea is the largest inland body of water on Earth. It contains salty rather than fresh water, so it can be appropriately described either as a salt lake or as an inland sea. The Caspian was once joined, via another inland sea, the Black Sea, to the Mediterranean. However, several million years ago it was cut off from those other seas when water levels fell during an ice age. The sea has no outflow other than by evaporation, but it receives considerable inputs of water from the Volga River (supplying three-quarters of its inflow) and from the Ural, Terek, and several other rivers. Its surface level has changed

THE VOLGA DELTA

The huge triangular delta of the Volga River is visible in the bottom of this image, with the Caspian Sea stretching out beyond it to the south.

ANTARCTICA

Antarctic Ice Sheet LOCATION Covering most of Antarctica TYPE Continental ice-sheet

5.3 million sq. miles (13.7 million sq. km)

AREA

SATELLITE VIEW

This radar image shows the whole of Antarctica, with the larger, eastern section of its ice sheet on the left. The gray area around its coast is partly ice shelf and partly sea ice.

Some of Earth’s largest oil reserves underlie the Caspian Sea. The greatest concentration of proven reserves and extraction facilities is in its northeastern section.

throughout history in line with discharges from the Volga, which in turn have depended on rainfall levels in the Volga’s vast catchment basin in Russia. Today, the Caspian Sea contains about 18,800 cubic miles (78,200 cubic km) of water—about one-third of Earth’s inland surface water. Its salinity (saltiness) varies from 1 percent in the north, where the Volga flows in, to about 20 percent in Kara-Bogaz-Bol Bay, a partially cutoff area on its eastern shore.

THE BEARDMORE GLACIER

This huge glacier drains the East Antarctic Ice Sheet into the Ross Ice Shelf. At 260 miles (415 km) in length, it is one of the longest glaciers on Earth.

Antarctic Ice Sheet is shrinking due to global warming. Scientists agree that the West Antarctic Ice Sheet has been showing a general pattern of retreat for over 10,000 years, but think there is only a small risk that it will collapse within the next few centuries.

THE LARSEN ICE SHELF

Around the coast of Antarctica, glaciers and ice streams merge to form platforms of floating ice called ice shelves. These are home to large colonies of penguins.

TH E S OL A R S Y S TE M

Earth’s largest glacier, the Antarctic Ice Sheet, is an immense mass of ice that covers almost all of the continent of Antarctica and holds over 70 percent of Earth’s fresh water. The ice-sheet has two distinct parts, separated by a range of mountains called the Transantarctic Range. The West Antarctic Ice Sheet has a maximum ice thickness of 2.2 miles (3.5 km), and its base lies mainly below sea level. The larger East Antarctic Ice Sheet is over 2.8 miles (4.5 km) thick in places with a base above sea level. Both parts of the ice sheet are domed, being slightly higher at their centers and sloping gently down toward their edges. A few areas around the edges of the ice sheets,

such as some regions within the Transantarctic Range, are known to be rich sources of meteorites (see pp.220–21). Meteorites continually fall onto the ice sheet and become buried in it. But in a few places, where there is an upward flow of ice and some evaporation, they concentrate again at the surface. For some years, there have been concerns that the West

OIL EXTRACTION

136

THE MOON

THE MOON EVEN THOUGH IT HAS ONLY

1.2 percent of the mass of Earth, the Moon is still the fifth-largest planetary 64–67 Celestial cycles satellite in the solar system. When full, it is the 102–103 The family of the Sun brightest object in our sky after the Sun, and its Meteorite impacts 221 gravity exerts a strong influence over our planet. However, the Moon is too small to retain a substantial atmosphere, and geological activity has long since ceased, so it is a lifeless, dusty, and dead world. Twelve men have walked on its surface and over 838 lb (380 kg) of lunar rock have been collected, but scientists are still not sure exactly how the Moon formed. 38–39 Gravity, motion, and orbits

ORBIT

same face always

Earth

points at The Moon has an elliptical orbit around Earth the Earth, so the distance between the two bodies varies. At its closest to Earth DAY 1 (perigee), the Moon is 10 percent closer than when at its farthest point (apogee). Moon rotates The Moon takes 27.32 Earth days to spin counterclockwise on its axis, which is the same time it takes to orbit the Earth. This is known as direction of synchronous rotation (see right) and keeps Moon’s orbit DAY 8 one side of the Moon permanently facing Earth—although eccentricities in the SYNCHRONOUS ROTATION Moon’s orbit called librations allow a few For each orbit of Earth, the Moon spins regions of the far side to come into view. once on its axis. As a result, it always Because the Earth is moving around the keeps the same face toward Earth. Sun, the Moon takes 29.53 Earth days to return to the same position relative to the Sun in Earth’s sky, completing its cycle of phases (see p.66). This is also the length of a lunar day (the time between successive sunrises on the Moon).

Moon spins on its axis every 27.32 Earth days

axis tilts from the vertical by 6.7˚

APOGEE 251,966 miles (405,500 km)

PERIGEE 225,744 miles (363,300 km)

Earth’s equator

TH E S O LA R S YS TEM

STRUCTURE

SPIN AND ORBIT

The Moon’s orbital path is tilted at an angle to Earth’s equator, causing its path across the sky to vary in an 18-year cycle. Tidal forces mean that the Moon is slowing down Earth’s rotation, while the Moon moves away from the Earth at a rate of about 1 in (3 cm) each year.

Moon orbits Earth in 27.32 Earth days

The lunar crust is made of calcium-rich, granite-like rock. It is about 30 miles (48 km) thick on the near side and 46 miles (74 km) thick on the far side. Because of the Moon’s history of meteorite bombardment, the crust is severely cracked. The cracks extend to a depth of 15 miles (25 km); below that, the crust is completely solid. The Moon’s rocky mantle is rich in silicate minerals but poor in metals such as iron. The upper mantle is solid, rigid, and stable. Radioactive decay of minor components of the lunar rock means that the temperature increases with depth. The lower mantle lies about 600 miles (1,000 km) below the crust, and here the rock gradually becomes partially molten. The average density of the Moon indicates that it might have a small iron core. The Apollo missions measured the velocities of shock waves traveling through the Moon, but the results proved inconclusive. Further seismic evidence is needed to confirm the existence of a metallic core.

rocky mantle

possible small metallic core crust of granite-like rock

MOON INTERIOR

The density of the Moon is much less than that of the whole Earth, but is similar to that of Earth’s mantle. It is possible that the Moon is entirely made of solid rock and has no metallic core at all.

THE MOON THE LUNAR SURFACE

This Apollo 16 image is centered on the boundary between the near and far sides of the Moon—a view never seen before the era of spaceflight. At least 4 billion years of asteroid bombardment has saturated the lunar surface with craters.

137

MOON PROFILE

AVERAGE DISTANCE FROM EARTH

ROTATION PERIOD

238,900 miles (384,400 km)

27.32 Earth days

SURFACE TEMPERATURE

LENGTH OF A DAY ON THE MOON

–240ºF to 240ºF (–150ºC to 120ºC)

29.53 Earth days

DIAMETER

2,160 miles (3,476 km)

MASS (EARTH = 1)

0.012

VOLUME (EARTH = 1)

0.02

GRAVITY AT EQUATOR (EARTH = 1)

NUMBER OF MOONS

0

SIZE COMPARISON EARTH

OBSERVATION

0.165 MOON

The amount of the sunlit Moon visible from Earth varies throughout the month, starting with a thin crescent in the western sky just after sunset. The month ends with a thin crescent moon visible in the east just before dawn.

ATMOSPHERE The Moon has a very thin, tenuous atmosphere with a total mass of about 22,000 lb (10,000 kg). This is the same as the amount of gas released by a landing Apollo spacecraft. The surface temperature varies by about 480˚F (270˚C) over a lunar day, and the quantity of gas near the surface is 20 times greater during the cold lunar night than during the heat of the day. The ATMOSPHERIC COMPOSITION Moon’s gravity is just one-sixth of The neon, hydrogen, and helium Earth’s, and the lunar atmosphere is have been captured from the escaping all the time. However, the solar wind. The argon is derived atmosphere is also constantly being from the radioactive decay of replenished by the solar wind. potassium in the lunar rocks. neon 29%

helium 25.8%

hydrogen 22.6%

argon 20.6%

trace gases

HISTORY OF THE MOON No one knows exactly how the Moon was formed, but most astronomers agree with the giant-impact theory, which hypothesizes that the process was set in motion about 4.5 billion years ago, when a massive asteroid hit the young Earth (see below). During the first 750 million years of its life, the Moon went through a period of heavy meteorite bombardment, which cracked the crust and created craters all over the surface. About 3.5 billion years ago, the rate of bombardment slowed and there followed a period of considerable volcanic activity. Lava from 60 miles (100 km) below the surface oozed up through cracks in the crust and filled large, low-lying craters. The lava solidified, producing the dark, flat basaltic areas called maria. This volcanic activity stopped about 3.2 billion years ago, and since then the Moon has been relatively dead. Many of the features formed in the early days of the Moon’s history have been destroyed by subsequent impacts. One of the most recent large craters is Copernicus, which was produced about 900 million years ago. FORMATION OF EARTH’S MOON

The majority of the ejected material went into a circular orbit around Earth, forming a clumpy, dense, doughnut-shaped ring.

3

Rocks grew by mutual collisions until a single body dominated the ring, sweeping up the remaining material. The Moon was born.

4

TH E S OL A R S Y S TE M

2 The ejected material formed a In a glancing collision between a Mars-sized asteroid and Earth, a huge massive cloud of gas, dust, and rock. amount of silicate material was jetted Heat was radiated away and the away from Earth’s mantle. cloud quickly began to cool.

1

138

THE MOON MYTHS AND STORIES

WEREWOLVES Many myths and old folk tales attribute strange powers to the Moon. Some say that a full moon can turn people mad (the origin of the word “lunacy”), and many cultures, from Eurasia to the Americas, share a belief that when the moon is full some humans can be transformed into vicious werewolves. The superstition is widespread and ancient—even the Babylonian King Nebuchadnezzar (c. 630-c. 562 bc) imagined that he had become a werewolf.

LUNAR INFLUENCES

inertial force

tidal bulge

Although the Moon is much smaller than Earth, its gravity still exerts an influence. The Moon’s gravitational attraction is felt most strongly on the side of Earth facing the tidal bulge Moon, and this pulls water in the oceans toward it. Inertia (the tendency of objects TIDAL BULGES Gravitational interaction between Earth with mass to resist forces acting upon and the Moon creates two bulges in Earth’s them) attempts to keep the water in place, oceans (exaggerated here). As Earth spins on but because the gravitational force is its axis, the bulges of water sweep over the greater, a bulge of water is pulled toward surface, creating tides. the Moon. On the opposite side of Earth, the water’s inertia is stronger than the TIDAL RANGE Moon’s gravity, so a second bulge of water is created. As The magenta in this Earth rotates, the bulges sweep over the planet’s surface, satellite image of Morecambe Bay on the creating daily changes in sea level called tides. The time of northwest coast of the high tide changes according to the Moon’s position in England reveals the the sky. The height of the tides changes during the lunar inlets and mud flats cycle, but the actual height also depends on local geography. that are left exposed at low tide. In shallow coastal bays, the tidal range can be huge.

gravitational pull of Moon

Moon’s orbit

Earth’s spin causes tidal bulges to sweep over surface

SURFACE FEATURES

LAVA TUBE

TH E S O LA R S Y S TE M

Over 3 miles (5 km) wide and hundreds of miles long, this rille is a collapsed tubelike structure through which lava once flowed. Moonquakes caused by nearby impacts may have caused the roof to fall in.

TRACKS IN THE SOIL

Lunar Rover tire tracks lead away from the Apollo 15 module “Falcon,” nestling near Hadley Rille in 1971. Over a million or more years, they will eventually be erased by meteorite bombardment.

The surface of the Moon has been pulverized by meteorites and is covered by a rough, porous blanket of rubble several yards thick. This debris ranges in size from particles of dust to huge lumps of rock dozens of yards across. The soil (or regolith) consists of finegrained, fragmented bedrock, the size of the MOON ROCK This 6-in- (15-cm-) wide rock grains getting progressively larger with formed as lava from the interior depth. Since there is no wind or rain, the rose to the Moon’s surface and surface material does not move far, and its solidified. The small holes were composition can change considerably from formed as gas bubbles escaped. place to place. The thickness also varies—in young mare regions it is about 16 ft (5 m) thick, but this increases to 32 ft (10 m) in the old highlands. Micrometeorite impacts continuously erode exposed rocks, and they are also damaged by cosmic rays and solar-flare particles. The topmost layer of soil is saturated with hydrogen ions absorbed from the solar wind.

THE MOON

CRATERS

139

SUNRISE OVER COPERNICUS CRATER

The vast majority of lunar craters are produced by impacts. Asteroids usually strike the Moon at velocities of about 45,000 mph (72,000 km/h). The resulting crater is about 15 times larger than the impacting body. Unless the asteroid nearly skims the surface on entry, the resultant crater is circular. Three types are formed. Those smaller than 6 miles (10 km) across are bowl-shaped, having a depth of around 20 percent of the diameter. Craters between 6 and 90 miles (10–150 km) in diameter have outer walls that have 1 Just after dawn in the crater, the slumped into the initial crater pit. There is often a low eastern Sun casts long shadows, central mountainous peak produced by the recoil of which emphasize the variation in the underlying stressed rocks. The crater depth is a height between the floor and rim. few miles, and much excavated material falls back into the crater just after the impact. Craters wider than 90 miles (150 km) contain concentric rings of mountains, created as rebounding material rippled out from the center before solidifying. Such craters were so deep that hot magma flooded to the surface and filled the bottom of the crater with lava.

Halfway through the morning, small 3 At noon, the Sun is overhead, and shadows enhance the ejecta blanket the scene appears much flatter and outside the crater. The temperature washed out. The temperature is now inside the crater is rising. more than 212°F (100°C).

2

RAY CRATERS

Material ejected from a crater during an impact is often confined to narrow jets. Where this material hits the surface, it plows up the lunar soil, and this disturbed region then reflects more sunlight than its surroundings. From Earth, these appear as rays. The rays around Tycho Crater (far right) extend for thousands of miles.

EUGENE SHOEMAKER Gene Shoemaker (1928–1997) was an American astrogeologist who studied terrestrial and lunar meteorite impact craters and dreamed of going to the Moon. Addison’s disease prevented that. Instead, he taught the Apollo astronauts to be field geologists. In 1969, he joined a team at Palomar, searching for nearEarth asteroids. After Shoemaker died, some of his ashes were carried to the Moon aboard the Lunar Prospector space probe in 1999.

MAPPING THE MOON

1610, emphasized the roughness of the surface.

SMART-1

During its approach phase, ESA’s SMART-1 spacecraft took this image of an illuminated region of the far side, near the lunar north pole, on November 12, 2004, from a distance of about 37,250 miles (60,000 km).

LUNAR ORBITER IV

This superb wide-angle image of the half-lit Mare Imbrium was one of 546 images taken by NASA’s orbiter on May 11–26, 1967, from a height of about 2,485 miles (4,000 km).

TH E S OL A R S Y S TE M

Some ancient Greeks thought that the Moon was like the Earth and that its dark areas were water. This belief continued into the 17th century, when the dark patches were given aquatic names such as mare (sea) and oceanus (ocean) on the first proper maps. Palus Putredinis (the Marsh of Decay) and Sinus Iridum (the Bay of Rainbows) are evocative examples. Italian astronomer Galileo Galilei was the first to realize that the height of surface features could be added LUNA 3 to maps by noting how the shadow lengths changed On October 7, 1959, the Soviet Union’s during the lunar day. The first photographic atlas Luna 3 space probe appeared in 1897, but the real leap forward came imaged the far side of with the advent of spaceflight. In 1959, the Soviet the Moon. It had never Union sent the Luna 3 space probe behind the been seen before. Moon to photograph the far side. NASA’s five Lunar Orbiter spacecraft imaged 99 percent of the lunar surface in 1966–67, paying special attention to potential Apollo landing sites. In the 1990s, the Moon’s mineral composition was surveyed by Clementine and Lunar Prospector. Since 2009, Lunar GALILEO SKETCHES Reconnaissance Orbiter (LRO) has Galileo’s first telescopic observations of the been engaged in a detailed Moon were made on November 30, 1609. The mapping project. pictures, published in Sidereus Nuncius in

140

THE MOON

THE NEAR AND FAR SIDES OF THE MOON

TOPOGRAPHIC VIEW

This map of lunar surface relief, colorcoded according to height, was produced by the altimeter on board NASA’s Lunar Reconnaissance Orbiter. Red areas are the highest, blue areas the lowest. This view is centered on the bright ray crater Tycho, with the Mare Orientale basin at left. The large, dark blue feature at the bottom is the South Pole–Aitken Basin (p.149).

The Moon’s spin and orbital periods became locked together very early in its existence, when it was much closer to Earth than it is now, and the surface was still molten due to the heating produced by massive early impacts. As a result, the Earth’s influence has led to noticeable differences in the appearance of the two sides. The far side is on average about 3 miles (5 km) higher, with respect to the Moon’s center of mass, than the near side, and its low-density crust is 16 miles (26 km) thicker. Since the near side is lower, volcanic magma has more easily found its way to the surface here, pouring from volcanic fissures into the low-lying regions of the largest craters and solidifying to form the lunar seas. By contrast, the far side—forever facing outward from Earth—lacks large seas and appears to have suffered heavier bombardment and cratering than the near side. MARE FRIGORIS ES

JU

RA

Plato Crater

IMB RE MA

Luna 17

RIU

Aristoteles Crater

M C MO A U N C TE A S S U S

M

T ON

Luna 2

Luna 21 Apollo 15 Luna 13

MARE S E R E N I TAT I S

Aristarchus Crater

MARE VA P O R U M Copernicus Crater

Kepler Crater Apollo 12

RE MA UM SI CRI

MONTES C AR PAT U S

Luna 9

Apollo 17

S TE US ON NIN M N E AP

O C E A N U S P RO C E L L A R U M

Luna 24

MARE T R A N Q U I L L I TAT I S

Surveyor 3 Luna 20

Ranger 8

Surveyor 1

MA E R FECUND I TAT I S

Apollo 14 Apollo 11 Ranger 7

Apollo 16

Grimaldi Crater

MA

Alphonsus Crater

RE

Theophilus Crater

OR

TA LE

Piccolomini Crater

Palus Epidemiarum

Tycho Crater N

270°

0°

Stöfler Crater

Petavius Crater

Hiten

NEAR SIDE

90°

Lunar Prospector S

Humboldt Crater

i

Valles Rheita

TH E S O LA R S YS TEM

MARE NUBIUM

MARE N E C TA R I S

lt a sA Rupe

IEN Darwin Crater

MARE HUMOR UM

Luna 16

Many features on the Moon’s near side have classically inspired names. Landing sites of the six crewed spacecraft and most of the probes that have reached the Moon (see panel, opposite) are marked on this map.

THE MOON

141

Pascal Crater

D’Alembert Crater Campbell Crater

Giordano Bruno Crater

MARE M O S C OV I E N S E Cockroft Crater

Mach Crater

Tsander Crater

Michelson Crater

Hertzsprung Crater Korolev Crater Doppler Crater Aitken Crater

Gagarin Crater Tsiolkovsky Crater

MARE INGENII

Apollo Crater

RI

Jules Verne Crater

M A EN RE TA LE

Van De Graaff Crater

O

Leibnitz Crater

N

FAR SIDE 90°

180°

Because Soviet probes were the first to see and image the far side of the Moon, many of the surface features are named after Soviet cities, scientists, and space pioneers.

270°

Schrodinger Crater S

SIGNIFICANT LANDINGS ON THE MOON Luna 17 (USSR)

November 17, 1970

Rover

Apollo 14 (USA)

February 5, 1971

Manned

Carries first robotic lunar rover Carries “lunar cart” for sample collection

Apollo 15 (USA)

July 30, 1971

Manned

Carries first manned lunar rovers

Luna 20 (USSR)

February 21, 1972

Lander

Makes automated sample return

April 21, 1972 December 11, 1972

Manned Manned

Explores central highlands Makes longest stay on Moon (75 hours)

MISSION

DATE OF ARRIVAL

TYPE

ACHIEVEMENT

Apollo 16 (USA) Apollo 17 (USA)

Luna 2 (USSR)

September 13, 1959

Impact

Makes first crash-landing on the Moon

Luna 21 (USSR)

January 15, 1973

Rover

Explores Posidonius Crater

Ranger 7 (USA)

July 31, 1964

Impact

Takes first close-up photos of surface

Luna 24 (USSR)

August 14, 1976

Lander

Returns sample from Mare Crisium

Ranger 8 (USA)

February 20, 1965

Impact

Takes 7,137 good-quality photos

Hiten (Japan)

April 10, 1993

Impact

Crashes into Furnerius region

Luna 9 (USSR)

February 3, 1966

Lander

Makes first soft landing

July 31, 1999

Impact

Surveyor 1 (USA)

June 2, 1966

Lander

Measures radar reflectivity of surface

Lunar Prospector (USA)

Orbiter makes controlled crash near the south pole to look for evidence of water

Luna 13 (USSR)

December 24, 1966

Lander

Successfully uses mechanical soil probe

SMART-1 (ESA)

November 14, 2006

Impact

Simulates a meteor impact with crash

November 14, 2008

Impact

Finds evidence of water

April 20, 1967 July 20, 1969

Lander Manned

Images future Apollo 12 landing site Lands first astronauts on the Moon

Chandrayaan-1 (India)

Apollo 12 (USA)

November 19, 1969

Manned

Makes first pinpoint landing

Chang’e (China)

March 1, 2009

Impact

Makes 3D map of lunar surface

Luna 16 (USSR)

September 20, 1970

Lander

Makes first automated sample return

LCROSS (USA)

October 9, 2009

Impact

Finds evidence of water

Surveyor 3 (USA) Apollo 11 (USA)

TH E S OL A R S Y S TE M

Between them, automated space probes and human explorers have studied a wide range of terrains on the near side of the Moon. At first, just crashing a probe into the Moon at all was a significant achievement, but by the time of the Apollo missions, landings were targeting particular areas to answer specific questions about the Moon’s geology and history.

EARTHRISE FROM APOLLO 8

In December 1968, the three-man crew of Apollo 8 became the first humans to orbit the Moon. They also became the first to see Earth rise over the Moon’s cratered surface, as in this image taken through the spacecraft’s window. Apollo 8’s pictures of Earth helped emphasize how small and fragile our home planet is and strongly influenced the environmental movement.

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FEATURES OF THE MOON From afar, the Moon is clearly divided into two types of terrain. There are large, dark plains called maria (Latin for “seas”) and also brighter, undulating, heavily cratered highland regions. The whole surface was initially covered with craters, most of which were produced during a time of massive bombardment. The rate at which asteroids have been striking the Moon has decreased over the last 4 billion years. Around 4 billion years ago, the Moon was also volcanically active. Lava rose to the surface through MOSAIC OF THE NORTH POLE cracks and fissures, filling the lower parts of the large The lunar North Pole is partially hidden from view from Earth and is best imaged craters to produce the dark plains. The plains reflect by orbiting spacecraft. Galileo took a only about 4 percent of the sunlight that hits them, series of photographs of the region on whereas the mountains reflect about 11 percent. December 7, 1992 on its way to Jupiter. NEAR SIDE northern hemisphere

Aristarchus Crater TYPE

Impact crater

About 300 million years AGE

DIAMETER

23 miles (37 km)

about 54°F (30°C) higher than that of the surrounding terrain. Young craters contain many large boulders. These take a long time to heat up during the day and also a long time to cool down at night. As time passes, the boulders are broken up by small impacting asteroids, so this thermal difference eventually disappears.

NEAR SIDE northern hemisphere

Mare Crisium Lava-filled impact crater (sea) TYPE

AGE

3.9 billion years

DIAMETER

350 miles

(563 km)

This young crater has a series of nested terraces, which were produced by concentric slices of rock in the wall slipping downward. This both widened the crater and made it considerably shallower, as the initially deep central region was filled with material from the rim. Aristarchus was mapped by the Apollo Infrared Scanning Radiometer. During the night, the temperature in the crater is

Mare Crisium has an extremely smooth floor, which varies in height by less than 290 ft (90 m). The lava that flooded Crisium had extremely low viscosity and became like a still pond before it solidified. The Soviet Luna 24 probe was the last mission to bring back rock samples from the Moon. In 1976, it returned to Earth with a core of rock weighing 6 oz (170 g), which was collected from Crisium’s floor.

LUNAR ORBITER 5 IMAGE

OVAL CRATER

This view of Aristarchus, taken from directly above, underlines the crater’s circularity and reveals the extensive surrounding blanket of hummocky ejecta.

The Mare Crisium, which can be seen with the naked eye from Earth, is nearly circular in shape. Over 95 percent of lunar craters are completely circular.

NEAR SIDE northern hemisphere

Montes Apenninus TYPE AGE

Mountain range 3.9 billion years

LENGTH

249 miles( 401 km)

NEAR SIDE northern hemisphere

Mare Tranquillitatis TYPE AGE

Sea 3.6 billion years

DIAMETER

542 miles

(873 km)

The Lunar Apennine mountains form a ring around the southeastern edge of the Mare Imbrium impact basin. They consist of crustal blocks rising more than 1.9 miles (3 km) above the flat lava plain, pushed up by the shock wave from the Imbrium impact. The mountain chain stretches for some 375 miles (600 km), though its southern end is partially buried beneath lava flows.

The surfaces of lunar maria are much darker than highland rock and are also considerably younger. This means that they are relatively smooth and contain only a few impact craters. Their low reflectivity is due to the chemistry of

LUNAR MOUNTAINS

BEFORE TOUCHDOWN

The Apennines lie in the lower right of this Apollo 15 image. The dark area to their left is Palus Putredinis.

The flat, desolate plain of the Sea of Tranquillity stretches away to the north in this view from the Apollo 11 lunar module taken just before landing.

the very fluid lava that flooded them. The Mare Tranquillitatis (Latin for “Sea of Tranquillity”) lies just north of the lunar equator and joins onto the southeast part of the Mare Serenitatis (Sea of Serenity). Together, the two seas form one of the Moon’s most prominent features. The basin in which the “sea” formed is very ancient, predating the formation of the Imbrium Basin 3.9 billion years ago. It overlaps with other basins at

RICH IN TITANIUM

This Galileo image has been color-coded according to the titanium content of the rock. The blue Tranquillitatis region is rich in titanium, whereas the orange Serenitatis region at the lower right is titanium-poor.

several points, but only flooded with lava about 3.6 billion years ago. The Sea of Tranquillity was famously the landing place of US astronauts Neil Armstrong and Buzz Aldrin on their 1969 Apollo 11 mission.

THE MOON NEAR SIDE northern hemisphere

Copernicus Crater TYPE AGE

Impact crater 900 million years

DIAMETER

57 miles (91 km)

This young ray crater has massive terraced walls. The crater floor is below the general level of the surrounding plain, and lies 2.3 miles (3.7 km) below the top of the LUNAR ORBITER 2 IMAGE

Copernicus Crater’s terraced walls and central peaks were revealed by NASA’s second Lunar Orbiter in 1966.

CRATER CHAINS

The material excavated by an impact showers down on the surrounding lunar surface, producing long chains of secondary craters.

surrounding walls. Copernicus is an intermediate-sized crater with high central peaks. These mountains were formed when the rock directly below the crater rebounded after being compressed by the explosion caused by the impacting asteroid. The vicinity of Copernicus is

peppered with secondary craters formed by boulders thrown out during the impact. Fine, light gray rock particles ejected during the crater’s formation were collected by the Apollo 12 astronauts near their landing site. Such particles were responsible for forming the rays that surround the crater. The high reflectivity of the rays is due to the ejecta churning up the lunar regolith (rough material reflects more light than smooth material).

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NEAR SIDE southern hemisphere

Alphonsus Crater TYPE

Impact crater

AGE

4.0 billion years

DIAMETER

80 miles (117 km)

NASA’s Ranger 9 spacecraft was deliberately crash-landed into the Alphonsus Crater on March 24, 1965, taking television pictures as it approached. The crater formed in an impact, but the dark patches and fractures Ranger 9 found on its floor are thought to be a result of volcanic activity—probably explosive eruptions. Because of these features, Alphonsus was considered a possible landing site for later Apollo missions.

THREE MINUTES BEFORE IMPACT

NEAR SIDE southern hemisphere

Humboldt Crater

Rupes Altai TYPE AGE

NEAR SIDE southern hemisphere

Cliff 4.2 billion years

LENGTH 315 miles (507 km)

TYPE

Impact crater

About 3.8 billion years AGE

DIAMETER

NEAR SIDE southern hemisphere

Tycho Crater TYPE AGE

Impact crater 100 million years

DIAMETER

52 miles (85 km)

120 miles

(189 km)

Altai is by far the longest cliff on the Moon. It is about 1.1 miles (1.8 km) high. The energy that is released during an impact does more than just excavate a crater and lift material out to form walls and an ejecta blanket. Violent seismic shock waves radiate away from the impact point. An obstacle such as a mountain can halt these waves and the lunar crust may then buckle, forming a long cliff. Altai was created by the Nectaris impact.

This crater is remarkable because its lava-filled floor is crisscrossed with a series of radial and concentric fractures (or rilles). On closer inspection, some look like collapsed tubes through which lava once flowed, others like rift valleys. Lunar volcanic activity lasted for over 500 million years. Lava would seep up into a crater and then cool, shrink, crack, and sink. It would then be covered by more lava. The final basaltic infill would have many layers.

The curving Rupes Altai— 310 miles (500 km) long—runs from top to bottom in this image. The crater at top left of the picture is Piccolomini.

CRACKS ON THE FLOOR OF HUMBOLDT

THREE FILTERED IMAGES OF TYCHO

The Ultraviolet/Visual camera onboard the Clementine spacecraft was equipped with a series of filters. Differing color combinations revealed the variability in the physical and chemical structure of the crater rock. YOUNGEST LARGE LUNAR CRATER?

Although Tycho is one of the youngest lunar craters (Giordano Bruno may be younger), it still formed in the age of the dinosaurs.

TH E S OL A R S Y S TE M

ALTAI ESCARPMENT

Lying in the southern highlands, Tycho is one of the most perfect walled craters on the Moon, with a central mountain peak towering 1.8 miles (3 km) above a rough infilled inner region. Surveyor 7 landed on the north rim of Tycho’s ejecta blanket in January 1968. About 21,000 photographs were taken, and the soil was chemically analyzed. The highland soil was found to be mainly made of calcium-aluminum silicates, in contrast to the maria material, which is iron-magnesium silicate.

146

THE MOON NEAR SIDE northern hemisphere

Taurus-Littrow Valley TYPE

Valley

About 3.85 billion years AGE

LENGTH

18.6 miles (30 km)

TH E S O LA R S YS TEM

In December 1972, the last crewed mission to the Moon landed in the dark-floored Taurus-Littrow Valley at the edge of the basalt-filled Mare Serenitatis. The range of geological features was impressive, and the Apollo 17 astronauts found three distinct types of rock in the region. One piece of crushed magnesium olivine was 4.6 billion years old and had crystallized directly from the melted shell of the just-formed Moon. The nearby Serenitatis crater

SHORTY CRATER

Harrison Schmitt stands by the Lunar Rover, parked to the left of the 356-ft- (110-m-) wide Shorty Crater. Behind Schmitt, 4 miles (6 km) away, is Family Mountain, one of the TaurusLittrow range named by the astronauts. Near the rover, patches of orange soil can be seen.

HIGHLAND MASSIFS

The flat-based TaurusLittrow Valley can be seen in the center of this image, nestling between the rugged, blocky mountains known prosaically as the North, South, and East massifs.

was produced about 3.9 billion years ago, and much of the basaltic rock dates from that time, when the crater was flooded with lava. The third type of rock was found on the top of nearby hills. This was barium-rich granite and had been ejected from one of the surrounding large craters. Most of the material near the landing site was extremely dark and consisted of cinders and ash ejected billions of years ago from nearby volcanic vents and fissures.

The Taurus-Littrow Valley is surrounded by steep-sided mountains, known as massifs. Moon mountains are different from those found on Earth. On Earth, the crustal plates collide, producing huge mountain ranges like the Alps and Himalayas. These new mountains are subsequently eroded by rain and ice. The Moon’s crust is not broken into plates. Nothing moves. All the Moon mountains are produced by impacts, and the mountains around the Taurus-Littrow Valley are the remains of old crater walls. Part of the valley floor just to the north of South

HARRISON SCHMITT Harrison “Jack” Schmitt (b. 1935) was born in New Mexico. He studied geology at Caltech and Harvard University. While working for the US Geological Survey, he joined a team instructing astronauts in the art of field geology. In June 1965, Schmitt was selected as a scientist-astronaut by NASA and was later chosen to be the lunar module pilot for Apollo 17. In December 1972, he became the first and only geologist to walk on the Moon. One of the highlights of the Apollo 17 mission was his discovery of orange glass within the lunar rock.

THE MOON Massif was covered with a light mantle of regolith a few yards thick. This had been produced by a rock avalanche, possibly triggered when the area was bombarded by boulders ejected when the nearby Tycho Crater was formed. As the Moon is being

continuously bombarded by asteroids, the number of craters per unit area increases with time. There are relatively few craters on the TaurusLittrow valley floor, which was taken to indicate that the surface is even younger than the Apollo 12 landing site. One crater in the valley, Shorty, was once thought to be a volcanic vent, but more detailed analysis of its raised rim and central mound indicated that, like millions of other lunar craters, it was produced by an impacting asteroid.

147

EXPLORING SPACE

MOON GLASS The lunar regolith contains large amounts of volcanic glass. This occurs as glazings on rock fragments and also as tiny teardrop- and dumbbell-shaped droplets. Colors range from green and wine-red through to orange and opaque. The orange glass found near Shorty was typical of high-titanium lunar glasses, but it was also rich in zinc. ORANGE SOIL IN SHORTY CRATER

The glassy orange surface soil was excavated by an impact about 20 million years ago. It was actually formed about 3.6 billion years ago.

SPLIT ROCK

This house-sized boulder was ejected from an impact crater in the Mare Serenitatis and then rolled down into the valley. Scoop marks can be clearly seen where some samples have been taken from its surface.

TH E S OLA R S Y S TE M

148

THE MOON FAR SIDE northern hemisphere

FAR SIDE southern hemisphere

Pascal Crater TYPE

Van de Graaff Crater Impact crater

Double impact crater

TYPE

About 4.1 billion years AGE

DIAMETER

AGE About 3.6 billion years

71 miles (115 km)

LENGTH

This is one of 300 lunar craters named after mathematicians. It honors the Frenchman Blaise Pascal. The image below was taken in 2004, with the camera looking directly down into the crater. The Sun is low in the sky, below the bottom of the picture. The tiny craters around Pascal are bowlshaped and young, with circular rims much sharper than the older rim of Pascal. The larger crater’s rim was initially eroded by slumping and rock slides, and is now being worn down further by more recent impacts.

FAR SIDE southern hemisphere

Tsiolkovsky Crater TYPE

Impact crater

About 4.2 billion years AGE

DIAMETER

123 miles

(198 km)

Only half the size of Mare Crisium, this far-side crater is special because only half the interior basin has been filled with lava. The central peak is also unusually offset from the center of the crater. There have been extensive rock avalanches down the ORBITER 3 IMAGE

PASCAL AND ITS YOUNGER NEIGHBORS

The crest of the rim of Tsiolkovsky Crater runs to the upper right of this image. The diagonal banding to its right is probably the result of a large avalanche down the slope of the rim.

DARK FLOOR

If Tsiolkovsky had been formed earlier in lunar history, the volcanic activity would have been greater and more of the crater floor would have been filled with lava.

southern rim of the crater. The first images of the lunar far side was obtained in October 1959 by the Soviet spacecraft Luna 3. Resolution was low, but the features that could be seen were nevertheless given names, such as Mare Moscoviense and Sinus Astronautarum. Only a few craters could be made out, including this one. Konstantin Tsiolkovsky was a Russian rocketry pioneer who not only designed a liquid hydrogen/liquid oxygen rocket but also suggested the multistage approach to spaceflight. The crater was penciled in as a possible landing site for one of the post-Apollo 17 missions, which were canceled.

155 miles (250 km)

Less than one percent of the lunar craters are noncircular. Van de Graaff is typical of such irregular craters, which are produced on the rare occasions when the impacting asteroid hits the surface at an angle of less than 4°. Van de Graaff is also special because it is both magnetic and has the highest concentration of natural radiation. Most of the ancient lunar magnetic field decayed away over 3 billion years ago. However, there are still a few magnetic anomalies (magcons), of which Van de Graaff and nearby Aitken are the strongest. Magcons were discovered by small magnetometer sub-satellites released by Apollos 15 and 16.

IRREGULARLY SHAPED CRATER

FAR SIDE southern hemisphere EXPLORING SPACE

Korolev Crater

NUCLEAR CRATER

Ringed impact crater

TYPE

It is very difficult to estimate the relationship between the size of a crater and the size of the asteroid that produced it. Usually the crater is about 20 times bigger. Only in controlled nuclear explosions can an exact relationship between energy release and crater size be established. Sedan Crater in the Nevada Desert (below) is bowlshaped and 1,200 ft (368 m) across. It was produced by a subsurface nuclear blast equivalent to 100 kilotons of TNT in July 1962. It is very similar to small lunar impact craters such as those within Korolev.

About 3.7 billion years AGE

DIAMETER

250 miles

TH E S O LA R S YS TEM

(405 km)

Sergei Korolev led the Soviet space effort in the 1950s and 1960s and was responsible for the early Sputnik and Vostok spacecraft. He has two craters named after him, one on the Moon and the other on Mars. Korolev is one of only 10 craters on the lunar far side that are more than 125 miles (200 km) across. It is double-ringed and pocked with smaller craters. The outer ring is 252 miles (405 km) in diameter. The inner ring is much less distinct. It is only half the height of the outer ring and its diameter is half that of the outer ring. Together with Hertzsprung and Apollo, Korolev forms a trio of huge ringed formations on the lunar far side. The lunar crust varies in thickness, and it reaches its maximum thickness of 66 miles (107 km) in the region around the Korolev Crater.

INDESTRUCTIBLE?

This Orbiter 1 image shows that later impacts have done little to obliterate the huge Korolev Crater.

THE MOON FAR SIDE southern hemisphere

FAR SIDE southern hemisphere

South Pole– Aitken Basin

Mare Orientale TYPE AGE

Multi-ring basin 3.8 billion years

DIAMETER

149

560 miles

(900 km)

TYPE

Impact crater

AGE

3.9 billion years 1,550 miles

DIAMETER

(2,500 km)

This multi-ring basin is half the size of the near side’s Mare Imbrium. It lies on the eastern limb of the far side, and from Earth the Montes Rook, the innermost eastern portion of the three distinct rings, can be clearly seen. This giant lunar bull’s-eye was formed by a massive asteroid, and two theories have been proposed to explain the rings. The first has the impact excavating a deep transient crater. The cracked inner walls of this crater would have been unable to support the weight of surrounding crust, so the rock slumped into the hole, guided by a series of concentric fault systems that account for the rings that remain. Not only was most of the crater filled in, but the breakup of subsurface rock allowed lava from far below the lunar surface to seep up and fill in the central regions. However, the highland crust is about 37 miles (60 km) thick, and rock from

ROOK AND CORDILLERA MOUNTAINS

Orientale is surrounded by two huge circular mountain ranges. The outer range is called Montes Cordillera (above right) and the inner one is called Montes Rook (lower left).

below that depth should have been excavated, but this deep rock has not been found. Alternatively, the seismic shocks generated by the massive impact could have briefly turned the surrounding rocks into a fluidized powder. Tsunami-type waves moved out through the pulverized rock but quickly became frozen, resulting in three clearly visible mountain rings.

The South Pole–Aitken Basin is an immense impact crater, lying almost entirely on the far side of the Moon. It stretches from just above the South Pole to beyond the Aitken Crater, which is close to the center of the far side. South Pole–Aitken is a staggering 1,550 miles (2,500 km) in diameter, and is over 7.4 miles (12 km) deep. It is one of the largest craters in the solar system, and is comparable in size to the Chryse Basin on Mars. It is about 70 percent of the diameter of Moon. The asteroid that produced it would have been over 60 miles (100 km) across. Even though the basin was first discovered in 1962, detailed investigation only started when the Galileo spacecraft imaged the Moon in 1992, while on its way to Jupiter. The South Pole–Aitken Basin looked darker than the rest of the far-side highland rocks, indicating that the lower-crustal rocks at the bottom of Aitken Crater

SOUTH POLE

The massively cratered, cold lunar South Pole can only be glimpsed tangentially from Earth. NASA’s Clementine mission provided the first detailed map of the region in 1994.

the deep crater were richer in iron than normal lunar surface material. Iron oxide and titanium oxide abound. Impact geophysicists are convinced that a normal impact could not have produced a crater this large without digging up large amounts of rock from the mantle that lies below the lunar crust. It may be that the crater was produced by a low-velocity collision, with the impactor coming into the surface at a low angle. Huge amounts of material would have been blasted from the lunar surface and would have moved off around the Moon’s orbit. In the subsequent 10 million years, this debris would have collided with the Moon, producing many new craters.

LARGEST KNOWN IMPACT CRATER

The South Pole– Aitken Basin, the largest impact scar on the Moon, is outlined on this relief map from the altimeter on NASA’s Lunar Reconnaissance Orbiter. The lowest areas are shown in blue, while the highest areas are shown in red and brown.

South Pole EXPLORING SPACE

LOOKING FOR WATER communications antennae

solar panels

neutron spectrometer

LUNAR BULL’S-EYE

Mare Orientale’s concentric rings can be seen in this composite Lunar Reconnaissance Orbiter image.

extendable booms

LUNAR PROSPECTOR

The South Pole-Aitken is one of the lowest regions on the Moon, and parts of it never see the Sun. Water seeping up from cracks in the mantle, or released by an impact, will not be able to escape from these “cold traps.” In 1998, Lunar Prospector found hydrogen, thought to be from the breakup of water ice, within these traps. Both the Chandrayaan-1 mission (2008) and LCROSS (2009) also indicate the presence of water in this region.

TH E S OL A R S Y S TE M

gamma-ray spectrometer

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MARS

MARS 38–39 Gravity, motion, and orbits 64–65 Celestial cycles 68–69 Planetary motion 100–101 The history of the solar system 102–103 The family of the Sun

MARS IS THE OUTERMOST

of the four rocky planets. Also known as the Red Planet because of its rust-red color, it is named after the Roman god of war. Its varied surface features include deep canyons and the highest volcanoes in the solar system. Although Mars is now a dry planet, a large body of evidence indicates that liquid water once flowed across its surface.

ORBIT Mars has an elliptical orbit, so at its closest direction approach to the Sun (perihelion) it receives of sunlight 45 percent more solar radiation than at the farthest point (aphelion). This means that the south polar region surface temperature can vary from -195˚F exposed to (-125˚C) at the winter pole, to 77˚F (25˚C) sunlight is ice-free during the summer. At 25.2˚, the current axial tilt of Mars is similar to that of Earth and, like Earth, Mars experiences changes in seasons as equator receives more the north pole, and then the south pole, points sunlight than toward the Sun during the course of its orbit. at 60° tilt Throughout its history, Mars’s axial tilt has fluctuated greatly due to various factors, including Jupiter’s gravitational pull. These fluctuations have caused significant changes in climate. When Mars is heavily tilted, the poles are more exposed to the Sun, causing water CHANGES IN AXIAL TILT ice-free ice to vaporize and Water-ice distribution during a equator Martian winter in the northern build up around the hemisphere varies with the axial colder lower latitudes. tilt. The translucent white areas At a lesser tilt, water ice shown here represent thin ice that becomes concentrated melts during the summer, whereas the thick white ice remains. at the colder poles.

axis tilts from vertical by 25.2°

NORTHERN SPRING EQUINOX

axis of rotation tilts 60° from vertical

60°

water ice concentrated at cold lower latitudes

water ice still present at equator 45°

water ice builds up at colder north pole

35° water ice concentrated around north polar region

25°

NORTHERN WINTER SOLSTICE

SPIN AND ORBIT

PERIHELION 128 million miles (207 million km)

APHELION 155 million miles (249 million km) Sun

TH E S O LA R S YS TEM

NORTHERN SUMMER SOLSTICE

Mars’s orbit is highly eccentric compared to that of Earth, which means that its distance from the Sun varies more during a Martian year. A Martian day is 42 minutes longer than an Earth day. Mars spins on its axis every 24.63 hours

Mars orbits Sun in 687 Earth days

NORTHERN FALL EQUINOX

STRUCTURE Mars is a small planet, about half the size of Earth, and farther away from the Sun. Its size and distance mean that it has cooled more rapidly than Earth, and its once-molten iron core is probably now solid. Its relatively low density compared to the other terrestrial planets indicates that the core may also contain a lighter element, such as sulfur, in the form of iron sulfide. The small core is surrounded by a thick mantle, composed of solid silicate rock. The mantle was a source of volcanic activity in the past, but it is now inert. Data gathered by the Mars Global Surveyor spacecraft has revealed that the rocky crust is about 50 miles (80 km) thick in the southern hemisphere, whereas it is only about 22 miles (35 km) thick in the northern hemisphere. Mars has the same total land area as Earth, since it has no liquid water on its surface.

small, probably solid iron core

mantle of silicate rock

MARS INTERIOR

rock crust

Mars has a distinct crust, mantle, and core. The core is much smaller in proportion to Earth’s, and has probably solidified.

MARS

151

MARS PROFILE

AVERAGE DISTANCE FROM THE SUN

ROTATION PERIOD

141.6 million miles (227.9 million km)

24.63 hours

SURFACE TEMPERATURE

ORBITAL PERIOD (LENGTH OF YEAR)

–195ºF to 77ºF (–125ºC to 25ºC)

687 Earth days

DIAMETER

4,213 miles (6,780 km)

0.11

MASS (EARTH = 1)

VOLUME (EARTH = 1)

0.15

GRAVITY AT EQUATOR (EARTH = 1)

NUMBER OF MOONS

2

SIZE COMPARISON EARTH

OBSERVATION

0.38 MARS

Mars is visible to the naked eye. It is brightest when at its closest to Earth, which is approximately once every two years. It then has an average magnitude of –2.0.

ATMOSPHERE AND WEATHER Mars has a very thin atmosphere, which exerts an average pressure on the surface of about 6 millibars (0.6 percent of the atmospheric pressure on Earth). The atmosphere is mostly carbon dioxide, and it appears pink because fine particles of iron oxide dust are SAND DUNES suspended in it. Thin clouds of Looking down into a small impact crater frozen carbon dioxide and water in a southern upland area called Noachis NASA’s Mars Reconnaissance Orbiter ice are present at high altitudes, Terra, captured these rippling sand dunes. The and clouds also form on high dunes were sculpted by Martian winds and peaks in the summer. Mars is a are shown here in enhanced color. The image is about 0.6 miles (1 km) across. cold, dry planet—the average surface temperature is -81°F (-63°C)—where it never rains, but in the winter clouds at the polar regions cause ground frosts. Mars has highly dynamic weather systems. In the southern spring and summer, warmer winds from the south blow into the northern hemisphere, stirring up local clouds of dust that can reach 3,000 ft (1,000 m) in height and last for weeks. The high-level winds can also create powerful dust storms that cover vast areas of the planet (see below). Mars also has low-level prevailing winds, which have sandblasted its surface for centuries, creating distinctive landforms (see photograph, above). oxygen, carbon monoxide, and trace gases (0.4%)

ATMOSPHERIC COMPOSITION

The thin atmosphere of Mars is dominated by carbon dioxide, with tiny amounts of nitrogen and argon and other gases, and some traces of water vapor.

argon (1.6%) nitrogen (2.7%)

carbon dioxide (95.3%)

SCARRED SURFACE

This mosaic of Viking Orbiter images shows Mars’s distinct red coloration and reveals the vast extent of the Valles Marineris, a system of valleys more than 2,500 miles (4,000 km) long.

On June 30, 1999, a storm system developed over the north polar region of Mars.

1

A giant, turbulent cloud of orange-brown dust was raised by high surface winds.

2

Expanding rapidly, the storm swirled over the white ice cap (center, top).

3

Six hours after the first image was taken, the storm was still gathering strength.

4

TH E S OL A R S Y S TE M

EVOLUTION OF A STORM SYSTEM

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MARS

MISSIONS TO MARS Numerous spacecraft have been sent to Mars since the first missions were undertaken by the USA and the Soviet Union in the 1960s, with varying success due to technical difficulties. A selection of successful missions is described below. 1976 VIKING 1 AND 2 (USA) These two craft each consisted of an orbiter and a lander. The orbiters sent back images, while the VIKING landers descended ORBITER to two different sites and sent back analyses of the soil and atmosphere, as well as images. 1997 MARS PATHFINDER (USA) This mission sent a stationary lander and a freeranging robot called Sojourner to the surface of Mars. They landed in an ancient floodplain and sent back pictures and analyses of soil samples. SOJOURNER

SURFACE FEATURES Mars’s surface features have been formed and shaped by meteorite impacts, by the wind (see p.151), and by volcanism and faulting (see Tectonic Features, below). Scientists also believe that water once flowed on and below the surface of Mars (see opposite), carving out features such as valleys and outflow channels. The craters formed during a period of intense meteorite bombardment about 3.9 billion years ago. They are found mainly in the southern hemisphere, which is geologically older than the northern hemisphere, and include the vast Hellas Basin (see p.165), but small craters are found all over Mars. Martian craters are flatter than those on the Moon and show signs of erosion by wind and water; indeed, some have almost been obliterated.

IMPACT CRATER

The Herschel impact crater, located in the southern highlands, is about 185 miles (300 km) across. This image has been false-colored to show altitude. The lowest areas are the dark blue floors of smaller craters. The Herschel Crater floor is mostly at 3,240 ft (1,000 m) and the highest parts of the rim (pale pink) are at about 9,720 ft (3,000 m).

SPIRIT AT HUSBAND HILL

The Spirit rover’s arm reaches out to investigate a rocky outcrop called Hillary, named after the mountaineer Sir Edmund Hillary, near the summit of Husband Hill.

TECTONIC FEATURES Billions of years ago, when Mars was a young planet, internal adjustments created the large-scale features seen on its surface today. Internal forces created raised areas on the surface, such as the Tharsis Bulge, and stretched and split the surface to create rift valleys, such as the vast Valles Marineris (see pp.158–59). Landslides, wind, and water have since modified the rift valleys.Volcanic activity dates back billions of years and persisted for much of Mars’s history. The planet may still be volcanically active today, although no such VALLES MARINERIS activity is expected. Lava The Valles Marineris is a complex system of eruptions of the past formed canyons that cuts across Mars at an average today’s giant volcanoes, including depth of 5 miles (8 km). If it was on Earth, it Olympus Mons (see p.157). would stretch across North America.

1997 MARS GLOBAL SURVEYOR (USA) Orbiting at an average altitude of 235 miles (380 km), the Global Surveyor mapped the entire planet at high resolution. It provided further evidence that water has flowed on Mars in the past. OLYMPUS MONS

2003 MARS EXPRESS (EUROPE) This orbiting spacecraft is imaging the entire surface of Mars as well as mapping its mineral composition and studying the Martian atmosphere.

This mosaic of images of Olympus Mons taken by Viking 1 in 1978 looks deceptively flat—the volcano stands 15 miles (24 km) above the surrounding plain.

2004 MARS EXPLORATION ROVERS (USA) Twin rovers Spirit and Opportunity landed on opposite sides of the planet and studied rocks and soil, looking for evidence of how liquid water affected Mars in MARS the past. ROVER

P ROTONIL US ME NSA E

U TO P I A P L A N I T I A NILOSYRT IS ME NSA E

TH E S O LA R S YS TEM

These four views combine to show the complete surface of Mars. They have been labeled to show large-scale features, as 0˚ well as the landing sites of some of the spacecraft sent to explore its surface.

NE

PE

E LY NT

HE

SIU

M

S M EN S

PL

AE

AN

IT

U TO P I A P L A N I T I A

Huygens Crater

TERRA TY R R H E N A

XANTHE TERRA

S

180˚

MA L E A P L A NUM

TERRA MERIDIANI

H E SP E RA P L A NUM

MARGARITIFER TERRA

Herschel Crater

N OAC H I S TERRA

N

Reull Vallis 270˚

Opportunity

TERRA SA

H E L L AS P L A NIT IA

N

IA

A

llis s Va Are

MARS MAPS

ISIDIS PLANITIA

allis Tiu V

SYRT IS MA J OR P L A NUM

2006 MARS RECONNAISSANCE ORBITER (USA) Looping over the poles of Mars 12 times every Martian day, MRO keeps a constant eye on the red planet’s weather and looks for signs of water, past or present, MRO on its surface.

CYDONIA MENSAE

Elysium Mons

Antoniadi Crater

DEUTER MEN

AC I DA L I A PLANITIA

Viking 2 Lander

P RO M E T H E I TERRA

ARGYRE PLANITIA 90˚

0˚

S

270˚

Galle Crater

MARS

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WATER ON MARS Scientists have been hoping to establish whether water is present on Mars, since this is essential for the development of life. Liquid water is not present, for this is a cold planet, where water can exist only as ice or vapor. The latter can form low-lying mists and fogs and freezes into a thin layer of white water ice on the rocks and soil when the temperature falls. However, dry river beds, valleys, and ancient floodplains bear witness to the presence of large amounts of fast-flowing water on the surface 3–4 billion years ago, when Mars was a warmer, wetter world with a thicker atmosphere. Some of that water remains today in the form of ice, THE CASE FOR FLOWING WATER Images from Mars Global Surveyor which is present both underground and have been processed to create this in the polar ice caps. The ice caps wax 3D view of seasonally variable and wane with the Martian seasons, and features on the inner slopes of the are composed of varying amounts of crater Newton, possibly created by running water. water ice and frozen carbon dioxide.

NORTH POLAR ICE CAP

The north polar cap of Mars, seen by Mars Global Surveyor, is about 600 miles (1,000 km) across and is cut by spiral-shaped troughs. At center right is Chasma Boreale, a valley about the length of Earth’s Grand Canyon.

MOONS

GEOGRAPHY

Mars has two small, dark moons called Phobos and Deimos, which were discovered by the American astronomer Asaph Hall in August 1877. Deimos, the smaller of the two, is 9.3 miles (15 km) long and Phobos is 16.6 miles (26.8 km) long. Both are irregular “potatoshaped” rocky bodies and are probably asteroids that were captured in Mars’s early history. They both bear the scars of meteorite battering. Deimos orbits Mars at a distance of 14,580 miles (23,500 km). Phobos is only 5,830 miles (9,380 km) from Mars and getting closer; eventually it will be so close that it will either be torn apart by Mars’s gravity field or collide with the planet.

The first reliable maps of Mars were made in the late 19th century when astronomers drew what they observed through their telescopes. Today’s maps are based on data collected by space probes such as Mars Global Surveyor, which obtained 100,000 photos of Mars and completed a survey of the planet, and Mars Express, which is imaging the entire surface. The following terminology is used for the surface features: lowland plains are termed planitia; high plains, planum; extensive landmasses, terra; and mountains or volcanoes, mons. A chasma is a deep, elongated, steep-sided depression, and a labyrinthus is a system of intersecting valleys or canyons. Individual names are allocated depending on the type of feature. Large valleys (vallis) are named after Mars in various languages and small ones after rivers. Large craters are named after past scientists, writers, and others who have studied Mars; smaller craters are named after villages. Other features are named after the nearest albedo feature on the early maps.

DEIMOS

PHOBOS Deimos completes a quarter of its orbit in the time it takes Phobos to orbit Mars

Phobos orbits Mars in 7 hours 39 minutes

MOONS’ ORBIT

Deimos completes orbit after 30 hours 18 minutes

ONI LU S SAE

ARCADIA PLANITIA

Mie

TEMPE TERRA

AL B A PAT E R A

AC I DA L I A PLANITIA

Acheron Fossae

Hecates Tholus

Arsia Mons

90˚

S

0˚

RI

NERIS

ES

NT

Herschel Crater

Apollinaris Patera Spirit

SOLIS P L AN U M

s ita ar ae Cl oss F

N

180˚

S I N AE P L AN U M

AEO MEN LIS SAE

I C AR I A P L AN U M

Lowell Crater

TERRA CIMMERIA

N

AO N I A TERRA

Kepler Crater 270˚

180˚

S

90˚

Ma’adim Vallis

DA E DAL I A PLAN U M

Noctis VA L L ES Labyrinthus M A

TERRA

Copernicus SIRENUM Crater Nansen Crater

DAEDALIA PLANUM

TH E S OL A R S Y S TE M

ABAEA

Olympus Mons

AMAZONIS PLANITIA

MO

AR

SI

S

L UNA E P L A NUM

Pavonis Mons

TH

Schiaparelli Crater

Albor Tholus

Simud Vallis

O

Ascraeus Mons

M

S

Elysium Mons

CHRYSE PLANITIA Nan edi Sha Vallis lba t Val ana lis

TE

N

Tikhonravov Crater

KASE

Olympus Mons

Belz Crater Mars Pathfinder

Mangala Valles

I VA LL

Cassini Crater

ARABIA TERRA

Viking 1 Lander

ES

SIS

Phobos and Deimos both follow near-circular orbits around Mars, and both exhibit synchronous rotation. From Mars, Phobos rises and sets three times every Martian day.

THAR

Mars rotates every 24 hours 37 minutes

THE LABYRINTH OF MARS

Noctis Labyrinthus (which is Latin for “labyrinth of the night”) is a complex system of steepwalled canyons at the western end of the giant Valles Marineris rift valley on Mars (see p.156). It is thought to result from faulting when the giant volcanoes on the Tharsis ridge of Mars caused the crust to bulge in this area. Landslides can be seen on the valley floors.

156

MARS

TECTONIC FEATURES Mars has two areas of markedly different terrain. Much of the northern hemisphere is characterized by relatively smooth and low-lying volcanic plains. The older southern landscape is typically cratered highland. The boundary between the two is an imaginary circle tilted by about 30° to the equator. The planet’s major tectonic features are found within a region that extends roughly 30° each side of the equator. It contains WESTERN FLANK OF OLYMPUS MONS Tectonic features on Mars take on familiar Mars’s main volcanic center, the Tharsis region, forms but are on a much grander scale than and the Valles Marineris, the vast canyon system those on Earth. This escarpment on the side that slices across the center of the planet. of Olympus Mons is 4.3 miles (7 km) high.

THARSIS MONTES

THARSIS MONTES

Pavonis Mons

Ascraeus Mons

TYPE

Shield volcano

TYPE

Shield volcano

AGE

300 million years

AGE

100 million years

DIAMETER

235 miles

DIAMETER

(375 km)

A huge bulge in the western hemisphere, commonly known as the Tharsis Bulge, contains volcanoes of various sizes and types, from large shields to smaller domes. Olympus Mons dominates the region. But three other volcanoes, which anywhere else would be considered enormous, are also found here. The three form a line and together make the Tharsis CHANNELS

These deep channels on the volcano’s southern flank may have started out as subsurface lava tubes whose roofs collapsed as pits developed over them.

285 miles

(460 km)

PIT CHAIN

A chain of pits lies in a shallow trough on the lower east flank. The pits and trough formed because the ground was either moved apart by tectonic forces or uplifted by molten rock.

Montes mountain range. Pavonis Mons, situated on the equator, is the middle of the three. It is a shield volcano with a broad base and sloping sides and is similar to those found in Hawaii on Earth. The volcano’s summit stands 4.3 miles (7 km) above the surrounding plain and has a single caldera within a larger, shallow depression. Hundreds of narrow lava flows are seen to emanate from the rim of the caldera, and others can be traced back to pits situated close by.

Ascraeus Mons is the northernmost of the three Tharsis Montes volcanoes. The three lie on the crest of the Tharsis Bulge and form a line in a southwest–northeast direction. The line marks the position of a major rift zone, long since buried under lava. The three volcanoes grew by the gradual buildup of thousands of individual and successive lava flows that came to the surface through the rift zone. Ascraeus is the tallest of the three, rising about 11 miles (18 km) above the surrounding plain. It has a large number of lines and channels all round the rim of the caldera, showing the paths taken by flowing lava.

CALDERA

The caldera on the summit is made up of eight major depressions and has a nested appearance (center). Its deepest point is over 1.9 miles (3 km) below the rim.

THARSIS MONTES

Arsia Mons TYPE

Shield volcano

AGE

700 million years

DIAMETER

295 miles

TH E S O LA R S YS TEM

475 km)

SUMMIT DEPRESSION

The summit caldera lies within a shallow depression that is almost twice the caldera’s size and has faulted sides.

Arsia Mons is second only to the mighty Olympus Mons in terms of volume. It is the southernmost of the three Tharsis Montes volcanoes, and its summit rises more than 5.6 miles (9 km) above the surrounding plain. Like the other two, it has a summit caldera bigger than any known on Earth. Arsia Mons measures 75 miles (120 km) across and is surrounded by arc-shaped faults. Lava flows fan out down the volcano’s shallow slopes. The lava is of basaltlike composition and of low viscosity, and the flows are shorter nearer the summit than on the lower flanks. CLOUDY SUMMIT

Water-ice clouds hang over the volcano’s summit—a common sight every Martian afternoon in the Tharsis region.

LAYERED OUTCROP

This outcrop of layered rock lies in a pit on the volcano’s lower west flank. The layers are thought to consist mostly of volcanic rock formed by successive lava flows.

MARS THARSIS REGION

Olympus Mons TYPE

Shield volcano

AGE

30 million years

DIAMETER

403 miles

(648 km)

on Earth. Olympus is one of the giant shield volcanoes of the Tharsis region, which is home to the greatest number of volcanoes on Mars, including the planet’s youngest. Volcanoes evolve over long periods of time and can be inactive for hundreds of millions of years. Olympus Mons is considered the youngest of the shield volcanoes. The summit has a complex caldera.

Olympus Mons is unquestionably the largest volcano in the Solar System. Its height, of about 15 miles (24 km), makes it the tallest, and its volume is over 50 times that of any shield volcano

Different areas of its floor are associated with different periods of activity. The largest central area, which is marked by ring-shaped faults, is more recent, at 140 million years old. The caldera is surrounded by a surface of wide terraces formed by lava flows, crossed by thinner flows. These are encircled by a huge scarp, up to 3.7 miles (6 km) high. Vast plains, termed aureoles, extend from the north and west of the summit like petals from a flower. These regions of gigantic ridges and blocks, whose origins remain unexplained, extend outward for up to 600 miles (1,000 km).

LAVA FLOWS

These lava flows and a collapsed lava tube (top left) on the southwest flank have been peppered by tiny impact craters.

157

EXPLORING SPACE

MARTIAN METEORITES Solidified basaltic lava covers the Tharsis region. Pieces of lava that flowed on the Martian surface as recently as 180 million years ago are now on Earth. Impactors hit Mars and ejected them, and after journeys lasting millions of years, they fell to Earth as meteorites. They include the Shergotty meteorite (right), which landed in Shergahti, India, on August 25, 1865.

MIGHTY OLYMPUS

This massive volcano is named after the mountaintop home of the gods and goddesses of Greek mythology. Broad lava-flow terraces surround the caldera at the volcano’s summit.

LANDSLIDE CLIFFS

In this bird’s-eye view of the 32-mile- (52-km-) wide nested caldera on the summit of Olympus Mons, five roughly circular areas of caldera floor can be seen.

Olympus Mons is bounded on all sides by steep cliffs, thought to have been caused by landslides. This close-up taken by Mars Reconnaissance Orbiter shows an area of the cliffs about 0.6 miles (1 km) wide on the northern side of the volcano.

TH E S OL A R S Y S TE M

COMPLEX CALDERA

158

MARS MESA

VALLES MARINERIS

This small mesa (a flat-topped hill) lies in northwestern Candor Chasma in the central Valles Marineris. Lighttoned outcrops of layered sedimentary rock are exposed on the top. These may have formed from material deposited in a lake in the chasma. Darker windblown ripples cover the surrounding plains.

Valles Marineris TYPE

Canyon system

About 3.5 billion years AGE

LENGTH Over 2,500 miles (4,000 km)

TH E S O LA R S YS TEM

Valles Marineris is the largest feature formed by tectonic activity on Mars. It consists of a system of canyons that stretches for over 2,500 miles (4,000 km), is up to 430 miles (700 km) wide, and averages 5 miles (8 km) in depth. The Grand Canyon in Arizona is dwarfed by comparison; it is only about one-tenth as long and one-fifth as deep. Valles Marineris lies just south of the Martian equator, and the system trends, very roughly, west to east. The trend follows a set of fractures that radiates from the Tharsis Bulge at Marineris’s western end. The origins of the system date back a few billion years to when the canyons were formed by faulting. This contrasts with the Grand Canyon,

SCARRED PLANET

Valles Marineris extends about a quarter of the way around Mars. All but the extreme western end of the canyon system is shown here. This image covers the area from the equator (top) to 20° south.

which is a primarily water-eroded canyon. But water, as well as wind, has played its part in the development of the Marineris system. Buffeting winds, flowing water, and the collapse of unstable walls have all widened and deepened the canyons.

The Noctis Labyrinthus region marks the western end of the system. This is a roughly triangular area of intersecting rift valleys that form a mazelike arrangement. The eastern end of Valles Marineris is bounded by chaotic terrain of irregular appearance. Here, smaller canyons and depressions give way to outflow canyons. These carried ancient rivers of water out of Marineris toward the lowland region, Chryse Planitia, to the north. This whole area has seen extensive water erosion; millions of cubic miles of material have been removed by water action. The system’s canyons are described as chasma (plural chasmata) and are given identifying names. The main chasma in the western part of the system is Ius. The central complex is made up of three parallel canyons, LAYERED DEPOSITS

A detail of the floor of western Candor Chasma shows layered sedimentary rock. Up to 100 layers have been counted, each about 30 ft (10 m) thick. The layers may be made from material deposited in an impact crater before the chasma formed.

MARS Ophir and Candor and, to their south, Melas Chasma. The long Coprates Chasma stretches out to the east, where it meets the broader Eos Chasma. The name of the whole system,Valles Marineris, means “Valleys of the Mariner.” The Mariner in this case is the Mariner 9 mission that mapped the entire surface of LOOKING WEST THROUGH OPHIR CHASMA

Over billions of years, Ophir Chasma has widened as its walls have collapsed and slumped downward, covering the floor with debris.

EASTERN EOS CHASMA

EXPLORING SPACE

Water flowed through this broad chasma, out of the Valles Marineris and into a series of valleys and channels.

Mars and took the first close-up images of this area. More recent craft, such as Mars Global Surveyor and Mars Express, have provided more detailed coverage. For example, their surveys have revealed layered rock in the canyon walls that could be a profile of the different lava flows that built the plains that the canyons cut through. Rocks on the floor may have formed from windborne dust layers or by deposits in ancient lakes that once filled the canyons.

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MARS EXPRESS’S STEREO CAMERA The High Resolution Stereo Camera onboard Mars Express began its two-year program to map the entire Martian surface in January 2004. Its nine chargecoupled device sensors record data one line at a time. Downward, backward, and forward views are used to build up 3-D images. The Super Resolution Channel provides more detailed information. Digital Unit includes Camera Control Processor

camera head

DUST STORM

Wind blows through the canyons carrying dust. The pinkish dust cloud at the bottom of this image is moving north across the junction of Ius Chasma and Melas Chasma. The higher, bluish-white clouds are water ice.

instrument frame provides mechanical stability

Super Resolution Channel

TH E S OL A R S Y S TE M

160

MARS BROKEN CRUST

THARSIS REGION

Acheron Fossae TYPE AGE

Fault system Over 3.5 billion years

LENGTH 695 miles (1,120 km)

Acheron Fossae is a relatively high area that has seen intense tectonic activity in the past. It marks the northern edge of the Tharsis Bulge

In this perspective view across the highly deformed area of Acheron Fossae, curved faults trending to the northwest dominate the scene.

and is located about 600 miles (1,000 km) north of Olympus Mons. Acheron is part of a network of fractures that radiates out from the Tharsis Bulge—a huge region of uplift and volcanic activity. It can be compared to the East African Rift on Earth (see p.130), where continental plates have spread apart. The huge curved faults in the Tharsis Bulge

CLIFF FACE

were produced in the process of the Tharsis uplift, and crustal cracks formed as hot mantle material pushed upward onto the surface rock layer. The brittle Martian crust broke along zones of weakness when the tension of the uplift became too strong. The eroded walls, the subdued nature of the highstanding hills, and the wind etching on the flat surfaces all confirm this is ancient terrain. This type of feature gets its name from the Latin fossa, meaning “trough.” In Greek mythology, Acheron is the river that flows into Hades, the Underworld.

A fault system cutting across an ancient impact crater is evidence of the stress felt by the Martian crust. The crater floor has since been resurfaced by material from outside the area.

GRABENS AND HORSTS

This is a close-up of the bright, steep slopes of a scarp or cliff. Dark streaks on the cliff face may be formed as the dust mantle that covers the region gives way and produces a dust avalanche.

The planetary crust has fallen between parallel faults to form grabens up to 1 mile (1.7 km) deep; remnants of the preexisting heights are termed horsts.

AONIA TERRA

CIMMERIA TERRA

Claritas Fossae

Apollinaris Patera TYPE

Patera volcano

TYPE

AGE

900 million years

AGE

DIAMETER

This is an example of a type of volcano that was first identified on Mars. Known as patera volcanoes, they have very gentle slopes (with angles as low as 0.25°). Apollinaris Patera is one of the largest on the planet, situated on the northern edge of Cimmeria Terra, a few degrees south of the equator. It is the only

Fault system Over 3.5 billion years

LENGTH 1,275 miles (2,050 km)

184 miles

(296 km)

T HE S O LA R S Y S TE M

STRESSED LANDSCAPE

MESAS AND TROUGHS

A group of mesas was created by pitting and erosion of the surface in an area north of Apollinaris Patera. Windblown dust has filled the troughs between the mesas.

major volcano that is isolated from the two major volcanic regions of Tharsis, to the northeast, and Elysium, to the northwest. Apollinaris is a broad, roughly shield-shaped volcano, reminiscent of an upturned saucer. It is only about 3 miles (5 km) high and has a caldera about 50 miles (80 km) across. It appears to have been formed by both effusive and explosive activity. Lava flows are clearly visible beyond the summit. A cliff surrounding the caldera area is visible on the northern side, but has disappeared on the opposite side. It is buried under a fan of material whose surface is marked by broad channels. The fan material could have formed from flowing lava or volcanic rock fragments. SPLIT-LEVEL CALDERA

The caldera has two different floor levels. It is partially hidden here by a patch of blue-white clouds. The summit area is pocked with impact craters.

LAVA BLANKET

Claritas Fossae is a series of roughly northwest-to-southeast-trending linear fractures, which forms the southern end of the Tharsis Bulge. It is located south of the equator at the western end of the Valles Marineris. The region is about 95 miles (150 km) wide at its northern end and 340 miles (550 km) wide in the south. Individual fractures range from a few to tens of miles across. They formed FAULTS IN CLARITAS FOSSAE

Running from the volcanic Tharsis Bulge, the linear features in this image of Claritas Fossae coincide with fractures in the Martian crust produced by stretching forces.

The eastern part of Claritas Fossae (bottom) meets the western part of Solus Planum (top). The lava from Solus has flowed over some of the older fractured terrain of Claritas and surrounds some of the higher ground.

as a result of enormous stresses associated with the formation of the Tharsis Bulge. As the crust pulled apart, blocks of crust dropped between two faults to form features called grabens. Crustal blocks that remained in place or were thrown up are termed horsts. Claritas Fossae separates two volcanic plains: that of Solis Planum to the east and Daedalia Planum to the west.

161

FEATURES FORMED BY WATER Both liquid and solid water have formed and shaped surface features on Mars. Giant channel-like valleys emerge fully formed out of the landscape. Some of these were cut during catastrophic floods, others were formed by water flowing more gradually through networks of river valleys, and others still were carved by glaciers. Some features suggest Mars once had seas, although the evidence is inconclusive. However, any REULL VALLIS potential rivers and seas have long since vanished, and Long, wide river channels are etched into the surface, revealing that huge only water ice remains, most markedly in the two ice volumes of water flowed across Mars plateaus that cap the planet. billions of years ago.

PLANUM BOREUM

North Polar Region TYPE

Polar ice cap

Under 2.5 billion years AGE

DIAMETER

685 miles

(1,100 km)

Two bright, white polar caps stand out against the otherwise dark surface of Mars. The one roughly centered on the North Pole is officially named Planum Boreum—the Northern Plain— although it is generally referred to as the North Polar Cap. Both this and its southern counterpart are easy to detect from Earth, but spacecraft have also flown over the poles, allowing monitoring of daily, seasonal, and longer-term change.

The North Polar Cap on Mars is an ice-dominated mound that stands several miles above the surrounding terrain. It consists of a virtually permanent cap of water ice, which is either covered by or free of a deposit of carbon-dioxide ice, depending on the time of the Martian year. The cap is roughly circular but—as is also the case for the South Polar Cap—its bright ice forms a distinctive swirling, loosely spiral pattern when seen from above (see p.163). The entire region is in darkness for about six months during the Martian winter. POLAR POLYGONS

Polygon-shaped structures, similar to those found in Earth’s polar regions, pattern parts of Mars’s polar landscape. On Earth, they form as a result of stresses induced by repeated freezing and thawing of water.

This is when carbon dioxide in the atmosphere condenses into frost and snow, and not only covers the water-ice cap, but also the surrounding region, down to latitudes of about 65° north. When spring turns to summer and the Sun is permanently in the polar sky, its warmth evaporates the carbon dioxide and turns some of the water ice directly into vapor. The polar cap shrinks until just water ice remains. The cap is not made exclusively of ice but consists of layers of ice and layers of dusty sediment. Frost grains form around small particles of dust during winter dust storms in much the same way that hailstones form on Earth. These cover the ground until the frost is evaporated in the warmer months, leaving a layer of dust. The yards-deep layers take

LAYERED DEPOSITS

Layers of ice at the Martian north pole attest to past variations in the planet’s climate. The layers are exposed at the edge of the ice sheet, which slopes downhill from the bottom to the top in this image. The thickness of the ice is about 0.6 miles (1 km).

millions of years to form, building up at the rate of about 0.04 in (1 mm) per year. A study of these layers will reveal the history of the Martian climate.

This close-up view of the Martian North Polar Cap shows water ice close to cliffs about 1.2 miles (2 km) high. Dark material in the caldera-like structures and dune fields could be volcanic ash.

TH E S OL A R S Y S TE M

CLIFFS NEAR THE NORTH POLE

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MARS UTOPIA PLANITIA

Utopia Planitia TYPE AGE

Lowland plain 2–3.5 billion years

DIAMETER

2,000 miles

(3,200 km)

Utopia is one of the enormous lava-covered plains of the northern hemisphere. The giant Elysium volcanoes are at its eastern perimeter. From above, it is possible to see that complex albedo patterns, polygonal fractures, and craters mark the vast rolling plain. Down on the surface, the landscape is uniformly flat and rock-strewn. At least that is the view in northeastern Utopia, where Viking 2 landed on September 3, 1976. Angular boulders of basaltic rock cover the landing site, close to Mie Crater. Small holes in the rocks are a

result of bursting are on a far bubbles of volcanic grander scale, the gas. A thin layer of size of a town or frost was also seen small city. The land by the craft, first in areas are 3–12 mid-1977, when miles (5–20 km) it covered the across, and the surface for about cracks between 100 Earth days, and them are hundreds then when it built of yards wide. up again in May Earth’s mud cracks 1979, one Martian form as ground year (23 Earth dries through POLYGON TROUGH FLOOR months) later. water evaporation. This close-up of one of the huge surface These giant The Martian cracks that isolate polygon-shaped areas polygons are not cracks could have of land reveals bright, evenly spaced unique to Utopia; a similar origin. windblown ripples of sediment. they are also seen Certainly, Mars on other northern plains such as has experienced the large-scale floods Acidalia and Elysium (below). They of water required. And dust-covered are polygon-shaped chunks of flat cemented rock found by Viking 2 land separated by huge cracks, or seemed to be held together by salts troughs, and are reminiscent of mud left behind as briny water vaporized. cracks seen in dried-up ponds on However, it has also been suggested Earth. Earth’s polygonal patterns are that the polygons formed in other book- to table-sized; the Martian ones ways—for example, in cooling lava.

LUNAR PLANUM

Kasei Valles TYPE

Outflow channel

AGE

3–3.5 billion years

LENGTH 1,105 miles (1,780 km)

Kasei, which takes its name from the Japanese word for Mars, is the largest outflow channel. Not only is it long, but parts of its upper reaches are over 125 miles (200 km) across and in places it is over 2 miles (3 km) deep. The catastrophic flooding that formed Kasei was greater than any other known flood event on Mars, or Earth. Kasei originates in Lunar Planum, directly north of central Valles Marineris (see p.158), then flows across the ridged plain to Chryse Planitia. Along its route lie streamlined islands, isolated as the water flow split and then rejoined.

ICE ON THE ROCKS

A coating of water ice covers the volcanic rocks and soil at the Viking 2 landing site. The ice layer is incredibly thin, no more than a thousandth of an inch (a fraction of a millimeter) thick.

ELYSIUM PLANITIA

Elysium Planitia TYPE

Lowland plain

Under 2.5 billion years AGE

DIAMETER

1,860 miles

TH E S O LA R S YS TEM

(3,000 km)

The Elysium Planitia is an extensive lava-covered plain just north of the equator. It has been suggested that an area almost directly south of the great volcano Elysium Mons is a dustcovered frozen sea. It is dominated by irregular blocky shapes that look like the rafts of segmented sea ice seen off

PLATEAU EDGE

This image shows the steep edge of a valley in northern Kasei Valles. The plateau to the left is about 0.8 miles (1.3 km) higher than the floor of the valley, similar to the depth of the Grand Canyon on Earth.

the coast of Earth’s Antarctica. These “ice plateaus” are surrounded by bare rock. They formed when water flooded through a series of fractures in the Martian crust, creating a sea similar in size to Earth’s North Sea. As the water froze, floating pack ice broke into rafts. These were later covered in dust from the nearby volcanoes, and this coating protected them. Unprotected ice between the rafts vaporized into the atmosphere, leaving bare rock around the ice plateaus. ICE PLATEAUS AND IMPACT CRATERS

The darker-toned ice plateaus are a few tens of miles across. The relatively small number of impact craters in this area suggests a young surface.

XANTHE TERRA

Nanedi Valles TYPE

Outflow channel

AGE

2–3.5 billion years

LENGTH 315 miles (508 km)

This major outflow channel lies in a relatively flat area. There is no visible source for the channel in the south, but its snakelike route northward, across the cratered plains of Xanthe Terra, is clearly seen before the channel comes to a sudden stop. Nanedi Vallis appears to have undergone different stages of flow. Initially, the meandering river almost created some oxbow lakes. Then, areas of riverbed drained and became the terraces now seen stranded between the main channel and the cratered plain above. A gully down the center of the channel indicates a final flow of water. TERRACING

Nanedi Vallis formed by water flow over a long period. Terracing is evident in this image, and a portion of the narrow central channel is just visible (top right).

MARS TERRA MERIDIANI

Meridiani Planum TYPE AGE

Highland plain Over 3.5 billion years

DIAMETER

680 miles

(1,100 km)

In the westernmost portion of Terra Meridiani and just south of the equator lies the high plain Meridiani Planum. It does not stand out in the

global view of Mars but achieved prominence as the landing site and exploration ground for the Opportunity rover. The plain is about 15° due west of Schiaparelli Crater (see p.164). Smaller impact craters pepper the area. They range from Airy, just 26 miles (41 km) across, to much smaller bowl-shaped craters, such as the 72-ft- (22-m-) wide Eagle Crater where Opportunity landed.

UNIQUE METEORITE

This basketball-sized rock has an iron-nickel composition. It is not a Martian rock but a meteorite—the first to be found on a planet other than Earth.

Volcanic basalt is found within the area, but the region is of greatest interest because it contains ancient layered sedimentary rock that includes the mineral hematite. Some of this mineral, which on Earth almost always

163

forms in liquid water, is exposed and easily found on the surface. The hematite could have been produced from iron-rich lavas, but it is believed that water was involved. This area is dry now but was once soaking wet and could well have been the site of an ancient lake or sea about 3.7 billion years ago. Eroded layered outcrops beyond the landing site support this theory and point to a deep and longlasting volume of water as large as Earth’s Baltic Sea. At this time, Mars must have been a much warmer and wetter place than it is today.

HEAT SHIELD AND SCORCH MARK

Subsurface pale dirt was spattered onto the plain when Opportunity landed. The remains of the craft’s discarded heat shield are at left and center.

PROMETHEI TERRA

Reull Vallis TYPE

Outflow channel

AGE

2–3.5 billion years

DIAMETER

587 miles

(945 km)

Reull Vallis is one of the larger channels of the southern hemisphere. It extends across the northern part of Promethei Terra, to the east of Hellas Basin (see p.165). Reull is thought to have had a complex evolution because it exhibits the characteristics of all three channel

types seen on Mars. In the collapsed region at the southern base of the volcano Hadriaca Patera, for example, it is a fully formed outflow channel. But small tributaries also feed into the main channel, as they would in a runoff channel. And the main channel has the features of a fretted channel—a wide, flat floor and steep walls. Reull Vallis takes its name from the Gaelic word for “planet.” MERGING CHANNELS

Reull Vallis (top left) is joined by a tributary, Teviot Vallis (right). The parallel structures in the fretted channel floor were possibly caused by a glacial flow of loose debris mixed with ice.

PLANUM AUSTRALE

South Polar Region TYPE

Polar ice cap

Under 2.5 billion years AGE

DIAMETER

900 miles

(1,450 km)

The South Polar Cap, known formally as Planum Australe (Southern Plain), is an ice-dominated mound a few miles high. It consists of three different parts. First is the bright polar cap that is roughly centered on the South Pole. This is a permanent cap of water ice with a covering of carbon-dioxide ice. Next are the scarps, made primarily of water ice, which fall away from the cap to the surrounding plains. Thirdly, hundreds of square miles of permafrost encircle carbon-dioxide frost covering

These spiderlike features in the south polar region of Mars were cut by dry ice (frozen carbon dioxide) as it turned to gas in the spring. The channels are 3–6 ft (1–2 m) deep.

the region. The permafrost is water ice mixed into the soil and frozen to the hardness of solid rock. The South Polar Cap shrinks and grows with the seasons like the North Polar Cap (see p.161). Yet surprisingly the southern cap does not get warm enough in the summer to lose its carbondioxide ice covering. Dust storms that block out the Sun may keep the cap cooler than expected. SOUTH POLAR CAP

Carbon-dioxide frost (shown as pink) covers over the water-ice cap (green-blue). Scarps of water ice at the edge of the cap slope toward the surrounding plains.

TH E S OL A R S Y S TE M

water ice, no carbon dioxide

SPIDERS ON MARS

164

MARS

IMPACT CRATERS The Martian surface is scarred by tens of thousands of craters, about 1,000 of which have been given names. They range from simple bowl craters, less than 3 miles (5 km) across, to basins hundreds of miles wide. The oldest craters are found in the southern hemisphere and have been eroded throughout their lifetimes. Their floors have been filled and their rims degraded, and the craters have become characteristically shallow. ANCIENT GEOLOGICAL FEATURE Smaller, fresher-looking craters have formed on top of Large impact craters such as Hale have had their central peaks them. The ejecta has been distributed by flowing across (right) and terraced walls continuously the surface rather than being flung through the air. eroded for up to 4 billion years.

MERIDIANI PLANUM

ARABIA TERRA

Victoria Crater TYPE

Schiaparelli Crater

Crater

TYPE

Under 100 million years AGE

DIAMETER

AGE

Large crater About 4 billion years

DIAMETER

0.5 miles

293 miles

(471 km)

(800 m)

Victoria is a small impact crater about two-thirds the size of the Arizona meteorite crater on Earth (see p.221). Victoria’s beautifully scalloped edges have been eroded by winds, gradually increasing its diameter, and like many Martian craters its floor is covered with dunes of wind-blown dust. The

CAPE ST. VINCENT

At Cape St. Vincent, a rocky outcrop on the northern rim of Victoria, layers of bedrock are topped by looser material thrown out by the impact that formed Victoria.

crater was explored by the Mars rover Opportunity over one Martian year (or two Earth years, from 2006 to 2008). Half of that time was spent driving along part of the crater’s rim before it carefully edged down a slope into the interior at an opening called Duck Bay. For the next Earth year, it examined rocky outcrops along the crater’s walls with the instruments on its robot arm, finally driving out again to resume its trek across the Martian surface. DUNE-FILLED CRATER

Rippling sand dunes cover the floor of Victoria, as seen in this enhanced-color view from the Mars Reconnaissance Orbiter.

MESAS

TERRA TYRRHENA

Smooth-topped hills (mesas) on the crater floor are left behind as a former smooth layer of material is eroded to reveal a more rugged surface.

Huygens Crater TYPE

Multi-ringed crater

AGE

About 4 billion years

DIAMETER

292 miles

TH E S O LA R S YS TEM

(470 km)

Huygens is one of the largest impact craters in the heavily cratered southern highlands of Mars. It was formed during the period of intense bombardment within the first 500 million years of the planet’s early history. The age of craters such as Huygens is determined by counting the number of craters that overlay their rims. Huygens has a second ring inside its mountainous rim. This has been filled by material carried into the ring. The rim is heavily eroded, and markings on it suggest that surface water has run off it at some

time. The pattern of markings is reminiscent of dendritic drainage systems on Earth, which from above look like the trunk and branches of a tree. Dark material within this crater’s drainage channels was carried either by the draining water or by the wind. EASTERN RIM

In this perspective view across Huygens’s eastern rim (foreground) to the surrounding terrain, a branchlike network of drainage channels flows away from the rim, and small, more recently formed craters can be seen.

This crater takes its name from the astronomer Giovanni Schiaparelli (see p.220), who spent much of his working life studying Mars. It is a highly circular crater, as are most Martian craters, although a significant number are elliptical—a rarity on the Moon and Mercury. Schiaparelli straddles the equator and is the largest crater in the Arabia Terra. It is an old crater, formed by an impacting body when the planet was young, and shows signs of degradation. The rim has been smoothed down and in parts is completely missing. Any central peak in the crater has been obliterated. Material has been deposited within the crater, and smaller craters have formed across the whole area. Wind continues to shape the landscape by erosion and by moving surface material.

WIND EROSION

These layers of ancient rock sediments on the floor of an impact crater lying within the northwestern rim of Schiaparelli have been eroded and exposed by the wind. SHALLOW CRATER

Here, color is used to indicate altitude. The crater floor is at the same height as much of the surrounding terrain. Higher deposits are in green. The degraded rim (yellow) is only about 0.75 miles (1.2 km) above the floor.

165 ROCK OUTCROPS

HELLAS PLANITIA

Hellas Planitia TYPE AGE

Basin About 4 billion years

DIAMETER

1,365 miles

(2,200 km)

The Hellas Basin is the largest impact crater on Mars and possibly the largest in the solar system. It is the dominant surface feature in the southern hemisphere. It is not immediately apparent that Hellas is an impact crater. Indeed, its official name, Hellas Planitia, indicates that it is a large, low-lying plain. This designation dates from over a century ago, when the Martian surface was observed only through Earth-based telescopes and the true nature of this vast, shallow feature was not known. Hellas is the Greek word for Greece. Particularly large craters that have been subsequently altered are termed basins. They are analogous to the maria on Earth’s Moon. The term basin is also applied to the second-largest Martian crater, Isidis Planitia, and the third-largest,

ANCIENT BASIN

The original crater floor has been covered by volcanic and wind-borne deposits, and it also shows signs of change by water and glacial ice. Dust storms continue to shape the surface.

SIRENUM TERRA

ARGYRE PLANITIA

Nansen Crater TYPE AGE

Large crater

DIAMETER

50 miles

(81 km)

CRATER WITHIN A CRATER

ERODED RIM

This perspective view shows the northern rim—the mountain range formed around the crater as the planet’s crust was lifted up at the time of impact. Whole portions of the rim are missing to the northeast and southwest.

TYPE AGE

Lowell Crater

Basin

About 4 billion years

DIAMETER

500 miles

CRATER DUNE FIELD

Argyre’s floor and rugged highland rim contain smaller craters. Some of these show signs of erosion. This one lying in the northwestern part of Argyre Basin contains a dark dune field.

Multi-ringed crater

AGE

About 4 billion years

DIAMETER

(800 km)

Argyre is the third-largest crater on Mars. Its floor has been flooded by volcanic lava, and it has been heavily eroded by wind and water. It is speculated that in the distant past, water drained into the basin from the south polar ice cap. Channels entering

TYPE

126 miles

(203 km)

FROST IN THE SOUTHERN HILLS

Frost (mainly of carbon dioxide) covers an area of cratered terrain in the Charitum Montes in early June 2003, at which time the south polar frost cap had been retreating southward for about a month.

the basin at its southeastern edge and others leading out from its northern edge reveal the water’s route. The path cuts through the mountain ranges that define the basin: the Charitum Montes to the south and the Nereidum Montes to the north.

Erosion has changed Lowell since its formation early in Mars’s history. The edges of both its outer rim and inner ring have been smoothed out, and its fine-grained ejecta soil has been blown around. The crater’s appearance continues to undergo long-term changes, but it also changes on a short-term basis. Frost covers the crater’s face in the winter months as the frost line extends north from the south polar region.

LOWELL IN WINTER

TH E S OL A R S Y S TE M

Martian impact craters were first identified in 22 images returned by Mariner 4 in 1966. Nansen Crater was among the first and was named after the Norwegian explorer Fridtjof Nansen. New craters continue to be added to the list as a result of surveys by spacecraft. The Viking orbiter recorded this image of Nansen in 1976. The crater shows signs of erosion; its walls have been nibbled by the wind. Smaller, sharply defined craters have punctuated the surrounding terrain. A more recent crater has formed inside Nansen. Its central dark floor could be volcanic basalt.

Argyre Planitia (below). Over the past 3.5–4 billion years, Hellas Basin has had its floor filled by lava and its features changed by wind, water, and fresh crater formation. Despite all this, some of its original features are still visible. Its overall shape and the remains of its rim can still be seen, as can inward-facing, arc-shaped cliffs lying up to several hundred miles beyond the rim. These are possibly the remnants of multiple rings.

AONIA TERRA

Argyre Planitia

About 4 billion years

Layered sedimentary rocks, which formed long after Hellas, lie in an eroded region northeast of the crater basin. Darker windblown ripples mark the surface.

166

MARS MERIDIANI PLANUM

Endurance Crater TYPE AGE

Bowl crater Under 4 billion years

DIAMETER

420 ft (130 m)

This small and inconspicuous crater has been explored and investigated to a greater extent than almost any other crater on Mars. In early 2004, it did not even have a name, but by the end of that year its rim, slopes, and floor had all been imaged and examined by the

robotic rover Opportunity. The small craft just happened to land within roving distance of this football-fieldsized crater when it made its scheduled landing in the Meridiani Planum in Mars’s northern hemisphere. Endurance, named after the ship that carried Irish-born British explorer Ernest Shackleton to the SAND DUNES

T HE SO LA R S Y S TE M

The center of the crater floor is covered by small sand dunes. The reddish dust has formed flowing tendrils, which are a few inches to a yard or so deep.

DRAMATIC PANORAMA

This approximately true-color view across Endurance Crater was taken by Opportunity’s panoramic camera as the rover perched on the western rim. A dune field lies in the center of the crater.

Antarctic, is an almost circular crater bounded by a rim of rugged cliffs. Its inner walls slope down to the crater floor, 66–100 ft (20–30 m) below. Layers of bedrock line the crater, some of which are exposed; loose material and sand dunes cover the rest of the floor. Opportunity spent approximately six months exploring Endurance. The rover started by traveling round the southern third of the crater’s rim; here it crossed a region named Karatepe and traveled along the edge of Burns Cliff. It then retraced its route to enter the crater on its southwestern limb.

BURNS CLIFF

This portion of the crater’s southern inner wall is called Burns Cliff. Forty-six Opportunity images taken in November 2004 combine to make this 180° view. The wideangle camera makes rock walls bulge unrealistically toward the viewer.

Opportunity made its way down the inner slope, examining rocks and soil along its route. It headed toward the crater’s center but got less than halfway before doubling back; any farther and it might have gotten stuck in the sandy terrain. It then exited the crater to

MARS WOPMAY ROCK

The 3-ft- (1-m) wide rock Wopmay (below) is one of the loose rocks on the crater floor. The image coloring highlights bluish dots in the rock, which are iron-rich spheres. The rover left wheel tracks in the soil (left) as it drove away from Wopmay.

move off across the adjoining flat plain, Meridiani Planum. The exposed layers of rock in walls such as Burns Cliff reveal what lies beneath the Martian surface, and what geological processes occurred there in the past. The composition of rocks on the crater floor, including

those named Escher, Virginia, and Wopmay, was analyzed and the finer-grained floor material was scrutinized. All the findings suggest that water has affected the rocks both before and after Endurance was formed.

167

EXPLORING SPACE

MARTIAN BLUEBERRIES Dark round pebbles nicknamed blueberries were found both within and on the terrain outside Endurance Crater. The name is, however, misleading; the pebbles, which appear bluer than their surroundings, are in fact dark gray. The half-inch blueberries are rich in the mineral hematite, which is also found on Earth. Hematite usually forms in lakes and hot springs on Earth, and this supports the idea that this part of Mars has had a watery past. A second type of round pebble that is lightercolored and rougher-textured has been nicknamed popcorn. EVIDENCE OF WATER

A mixture of blueberries and popcorn lies on top of a rock called Bylot inside Endurance Crater.

T HE SO LA R S Y S TE M

MARTIAN DUNE

Mars is a dusty planet, and winds blow the dust around to form fantastic shapes, reminiscent of those seen in deserts on Earth. Shown here, on the floor of an old Martian crater called Arkhangelsky, is a barchan dune. Barchan dunes are arc-shaped, with two horns that point downwind and a steep slope between. This false-color image was taken by NASA’s Mars Reconnaissance Orbiter.

170

ASTEROIDS

ASTEROIDS ASTEROIDS ARE REMNANTS OF

a failed attempt to form a rocky planet that would 38–39 Gravity, motion, and orbits have been about four times as massive as 100–101 The history of the solar system Earth. They are dry, dusty objects and Meteorites 222–23 far too small to have atmospheres. Over 200,000 have been discovered, although over a billion are predicted to exist. The astronomers who discover asteroids have the right to name them.

TU SA

RN

’S

EROS Orbital period 1.76 years JU

’S ER PIT

BIT OR

TROJANS Both groups of Trojans follow Jupiter’s orbit

O RB I T TH’S EAR

APOLLO Orbital period 1.81 years CERES Orbital period 4.6 years

ICARUS Orbital period 1.12 years

ORBIT

Most asteroids are found in a concentration known as the Main Belt, which lies between Mars and Jupiter, about 2.8 times farther from the Sun than Earth. Typically, they take between four and five years to orbit the Sun. The orbits are slightly elliptical and of low inclination. Even though the asteroids are all orbiting in the same direction, collisions at velocities of a few miles per second often take place. So as time passes, asteroids tend to break up. Some asteroids have been captured into rather strange orbits. The Trojans have the same orbital period as Jupiter and tend to be either 60° in front or 60° behind that planet. Then there are the Amor and Apollo asteroid groups (named after individual asteroids), with paths that cross the orbits of Mars and Earth, respectively. Aten asteroids have such small orbits that they spend most of their time inside Earth’s orbit. These three groups are classed as nearEarth asteroids. They can be dangerous, having the potential to hit Earth and cause a great deal of damage. Fortunately, this happens very rarely.

SUN

S RS’

ORBITS

MA

34–37 Radiation

T BI OR

MAIN BELT

ASTEROID PATH

To picture stars, the Hubble Space Telescope scans the sky, keeping the stars stationary in the image frame. Asteroids, being much closer than the stars and in orbit around the Sun, form streaky trails (the blue line) during the exposure time.

TH E S O LA R S YS TEM

STRUCTURES At the dawn of the solar system, there existed quite a few asteroids nearly as large as Mars. The radioactive decay of elements within the asteroidal rock melted these large bodies, and, during their fluid stage, gravity pulled them into a spherical shape before they cooled. Many of these have since been broken up or reshaped by collisions with other asteroids. Smaller asteroids, which cooled more efficiently than larger ones, did not reach melting point and retained a uniform rocky-metallic composition and their original irregular shape. There are three main compositional classes of asteroids. The vast majority are either carbonaceous (C-type) or silicaceous (S-type). The next most populated class is metallic (M-type). These classes correspond to carbonaceous chondrite (stony) meteorites, stony-iron meteorites, and iron meteorites.

direction of orbits

AMOR Orbital period 5.3 years

CERES

VESTA

ASTEROID SHAPES AND SIZES IDA

The largest asteroids, such as Ceres and Vesta, are nearly spherical, whereas smaller asteroids, such as Ida, are irregularly shaped. All asteroids have craters on their surfaces, but some areas have been sandblasted and smoothed by a multitude of minor collisions.

ASTEROIDS

171

ASTEROID ORBITS

Asteroids tend to stay close to the plane of the solar system, and they orbit in the same direction as the planets. A few individual asteroid orbits are shown here, together with the Main Belt. Asteroids often cross paths, suggesting that collisions are common. As time passes, more and more asteroids are produced, but the average size gets smaller and smaller.

TROJANS Orbital period 11.87 years

FRANZ XAVER VON ZACH Franz Xaver von Zach (1754–1832) was a Hungarian baron and the director of the Seeberg Observatory in Germany. He became convinced that there was a missing planet orbiting between Mars and Jupiter. In September 1800, he organized a group of 24 astronomers to help him look. Popularly known as the Celestial Police, they divided the celestial zodiac into 24 parts and started searching but were beaten by a nose by Giuseppe Piazzi’s accidental discovery of the asteroid Ceres in 1801. The Police were surprised by how small Ceres was, and then were surprised again when more and more asteroids were found in similar orbits.

direction of orbits

COLLISIONS The effect of a collision between asteroids depends on the sizes of the bodies involved. If a very small asteroid hits a larger one, it will produce a crater on the surface. This crater will be about 10 times the size of the incoming body. Since asteroids are much smaller than planets, the material blasted out of the crater will escape and move off into an independent orbit around the Sun. This orbit will, however, be very similar to that of the impacted asteroid, and there is a good chance that the ejected material will hit the cratered asteroid again. A bigger impactor can break up the asteroid that it hits. But so much energy is used to do this that the resulting fragments cannot escape from the gravitational field, and they will all fall back to form an irregular ball of rubble. Subsequent minor impacts will break up the surface, covering the asteroid in a rocky, dusty layer. A casual observer would not realize that the underlying asteroid is actually in pieces. A large impactor will not only shatter the asteroid, but the fragments will also escape. These will form a family of asteroids that eventually spreads out around the orbit of the original body.

HIDALGO Orbital period 13.7 years

CRATERING crater forms

ADONIS Orbital period 2.6 years impacting asteroid is less than 1/50,000th of size of larger body

asteroid forms dusty ball of rubble

FRACTURING rocky body fractures

SHATTERING

asteroid breaks into fragments of rock and dust

ASTEROID COLLISIONS

rocky body shatters into pieces

impacting asteroid is more than 1/50,000th of size of larger body

family of asteroids forms

There are far more small asteroids than large ones. For every asteroid more than 6 miles (10 km) along its longest axis, there are 1,000 longer than 0.6 miles (1 km) and a million longer than 0.06 miles (0.1 km). So cratering is much more common than fracturing, which in turn is much more common than shattering. Asteroids that are shattered are likely to be already fractured.

TH E S OL A R S Y S TE M

impacting asteroid is 1/50,000th of size of larger body

172

ASTEROIDS

ASTEROIDS Mainly moving between the orbits of Mars and Jupiter, asteroids are the remnants of a planet-formation process that failed. Today’s asteroid belt contains only about 100 asteroids that are larger than 125 miles (200 km) across. But there are 100,000 asteroids greater than about 12.5 miles (20 km) across and a staggering 1 billion that are over 1.25 miles (2 km) along their longest axis. Ceres, the first asteroid to be discovered, in EROS Only asteroids bigger than about 1801, is now also called a dwarf planet (see 215 miles (350 km) in diameter are p.175). Ceres contains about 25 percent spherical. Eros is an irregularly shaped of the mass of all the asteroids combined. fragment of a much larger body. MAIN-BELT ASTEROID

951 Gaspra

MAIN-BELT ASTEROID

5535 Annefrank

AVERAGE DISTANCE TO SUN

AVERAGE DISTANCE TO SUN

206 million miles (331 million km)

(331 million km)

ORBITAL PERIOD

3.29 years

ROTATION PERIOD LENGTH

7.04 hours

11.2 miles (18 km)

DATE OF DISCOVERY

July 30, 1916

Until 1991, asteroids could be glimpsed only from afar. In October of that year, a much closer view was obtained when the Galileo spacecraft flew within 1,000 miles (1,600 km) of Gaspra, taking 57 color images. Gaspra is a silicate-rich asteroid. The surface is very gray, with some of the recently exposed crater edges being bluish and some of the older, low-lying areas appearing slightly red.

ORBITAL PERIOD

3.29 years

ROTATION PERIOD LENGTH

206 million miles

Not known

3.7 miles (6 km)

DATE OF DISCOVERY

March 23, 1942

as it passed within 2,050 miles (3,300 km) on its way to Comet Wild 2. Annefrank turned out to be twice as large as had been predicted from Earth-based observations. The brightness that is detected from Earth is proportional to the reflectivity multiplied by the surface area, but astronomers had used too high a value for the reflectivity. The asteroid was named after the famous diarist Anne Frank, who died during the Holocaust.

Annefrank orbits in the inner regions of the Main Belt of asteroids and is a member of the Augusta family. On November 2, 2002, Annefrank was imaged by NASA’s Stardust spacecraft

SURFACE BRIGHTNESS

False colors (left) are used to highlight differences in brightness over the surface of the asteroid (above). The variations are mainly due to dusty soil layers reflecting different amounts of sunlight in different directions.

IRREGULAR SHAPE

MAIN-BELT ASTEROID

2867 Šteins

AVERAGE DISTANCE TO SUN

220 million miles (354 million km)

(365 million km)

3.63 years

ROTATION PERIOD DIAMETER

6.05 hours

4.14 miles (6.67 km)

DATE OF DISCOVERY

November 4, 1969

Some asteroids are not solid but consist of rock fragments with gaps between. One such example—termed a “rubble pile”—is Šteins, which the Rosetta space probe showed to be shaped like a cut diamond. The impact that produced its largest crater is thought to have fractured the asteroid.

DIAMOND IN THE SKY

ORBITAL PERIOD

AVERAGE DISTANCE TO SUN

234 million miles

(376 million km) ORBITAL PERIOD

4.03 years

ROTATION PERIOD LENGTH

5.4 and 7.3 days

2.65 miles (4.26 km)

DATE OF DISCOVERY

January 4, 1989

Toutatis was named after a Celtic god (who, incidentally, appears in the Asterix comic books). A typical nearEarth asteroid, it sweeps past the planet nearly every four years. In September 2004, it came as close as just four times the distance of the Earth to the Moon. Toutatis is an S-class asteroid, similar to a stonyiron meteorite in composition. It tumbles in space rather like a rugby ball after a botched pass, spinning around two axes, with periods of 5.4 and 7.3 days. RADAR IMAGE

253 Mathilde 227 million miles

AVERAGE DISTANCE TO SUN

246 million miles

(396 million km) 3.80 years

ROTATION PERIOD DIAMETER

4179 Toutatis

MAIN-BELT ASTEROID

21 Lutetia

AVERAGE DISTANCE TO SUN

ORBITAL PERIOD

TH E S O LA R S YS TEM

MAIN-BELT ASTEROID

NEAR-EARTH ASTEROID

ORBITAL PERIOD

8.17 hours

75 miles (121 km)

DATE OF DISCOVERY

LENGTH

November 15, 1852

Lutetia was the second of two asteroids visited by the European Space Agency’s Rosetta space probe, the first being 2867 Šteins (see left). At over 60 miles (100 km) across, Lutetia is one of the larger asteroids and is also one of the most dense, suggesting that it contains large amounts of iron and might once have had a molten core. Rosetta’s images, taken in July 2010, showed hundreds of craters up to 34 miles (55 km) wide and boulders as large as 1,000 ft (300 m) across on Lutetia’s battered surface. Lutetia may have been almost spherical before parts of it were chipped off.

4.31 years

ROTATION PERIOD

About 418 hours

41 miles (66 km)

DATE OF DISCOVERY

ROSETTA’S VIEW

Lutetia was photographed by Rosetta at its closest approach of 1,970 miles (3,170 km) in the top image. Craters and grooves on the asteroid’s surface are visible in the close-up (left).

Some of its craters have been partly or completely buried by landslides set off by the vibrations from later impacts. Lutetia seems to be a link between small “rubble pile” asteroids and terrestrial planets such as Earth.

November 12, 1885

Mathilde was visited by the NEAR Shoemaker space probe in 1997 but, because it spins very slowly, only about half of the surface was imaged. It is a primitive carbonaceous asteroid with a density much lower than that of most rocks, suggesting that it is full of holes. Mathilde is probably a compacted pile of rubble.

WEDGE-SHAPED CRATER

ASTEROIDS

MAIN-BELT ASTEROID

243 Ida AVERAGE DISTANCE TO SUN

266 million miles

(428 million km) ORBITAL PERIOD

4.84 years

ROTATION PERIOD LENGTH

4.63 hours

37 miles (60 km)

DATE OF DISCOVERY

September 29,1884

Ida was one of 119 asteroids discovered by the Austrian astronomer Johann Palisa, who, together with Max Wolf of Heidelberg, Germany, was a pioneer in the use of photography to produce star maps and hunt for minor planets (another name for asteroids). Ida is a member of the Koronis

family. Asteroidal families were discovered by the Japanese astronomer Hirayama Kiyotsugu in 1918. He found that there were groups of asteroids with very similar orbital parameters. The individual members were strung out on one orbit and formed a stream of minor bodies in the inner Solar System (see p.170). Koronis is the most prominent member of Ida’s family. Ida is famous because the Galileo spacecraft imaged it in detail as it flew within 6,800 miles (11,000 km) during August 1993, on its way to Jupiter. Because Ida makes a complete rotation every 4 hours 36 minutes, Galileo was able to image most of the surface during the flyby. Ida was originally thought to be an S-type

173

DACTYL

At just 1 mile (1.6 km) long, Dactyl is tiny. Its orbit around Ida is nearly circular, with a radius of about 56 miles (90 km) and an orbital period of about 27 hours.

asteroid like Gaspra (see opposite), but observations revealed that its density is too low and it is more likely to be a C-type asteroid. It has about five times more craters per unit area than Gaspra, indicating that its surface is considerably older. The most exciting outcome of the Galileo flyby was the discovery that Ida has its own moon, Dactyl. This binary system is thought to have been formed during the asteroid collision and breakup that created the Koronis family.

Dactyl was the first asteroid satellite to be discovered. Ann Harch, a Galileo mission member, noticed it when examining images that had been stored on the spacecraft when it passed Ida six months earlier.

TH E S OL A R S Y S TE M

IDA AND ITS MOON

174

ASTEROIDS MAIN-BELT ASTEROID

4 Vesta AVERAGE DISTANCE TO SUN

219 million miles

(353 million km) ORBITAL PERIOD

3.63 years

ROTATION PERIOD DIAMETER

5.34 hours

330 miles (530 km)

DATE OF DISCOVERY

March 29, 1807

Vesta is one of the largest asteroids, with a surface that reflects, on average, 42 percent of the incoming light. This makes it the brightest asteroid in the night sky and the only one that is visible to the unaided eye. Most asteroids of Vesta’s size are expected to be nearly spherical, but Vesta’s shape has been distorted by a massive impact at the south pole that created a huge basin called Rheasilvia, which measures some 300 miles (500 km) across—almost as wide as Vesta itself. Like many large craters on the Moon,

SNOWMAN CRATERS

TH E S O LA R S YS TEM

The three craters that form the “Snowman” are at the bottom left in this image. The smoother surface around them is thought to be a blanket of debris thrown out by the impacts.

Rheasilvia has a mountainous central peak. It overlaps an older and slightly smaller crater, which is 230 miles (375 km) wide. Some of the fragments of Vesta’s crust produced by the cratering process are still trailing Vesta on similar orbits. Others have hit Earth and been recognized as strange meteorites with a composition similar to the igneous rock basalt. Six percent of Earth’s recent meteorite falls are Vesta-like in their mineralogical makeup. The composition is similar

to the lava that spews out of Hawaiian volcanoes. In its early life, Vesta melted and then resolidified, with denser material sinking to the centre. It now has a layered structure like the rocky planets, with a low-density crust lying above layers of pyroxene and olivine and an iron core. Vesta is thought to be the only remaining differentiated asteroid in the Main Belt. It is one of the densest asteroids known, with a density similar to that of Mars. In July 2011, NASA’s Dawn spacecraft went into orbit around Vesta, beginning a yearlong study of the asteroid. Vesta’s surface turned out to be old and SOUTH-POLAR IMPACT BASIN

A giant impact basin called Rheasilvia at the south pole of Vesta is seen here in a false-color image taken by NASA’s Dawn spacecraft. It is 300 miles (500 km) across and has a central peak (shown in red) and a rim that is 9 miles (15 km) high.

METEORITE

This meteorite, which landed in Western Australia in October 1960, originated from Vesta.

heavily cratered, with grooves running around the equator, possibly fractures from the south-polar impact. One of the asteroid’s most distinctive features was a chain of three craters nicknamed the Snowman, seen in the image below. From top to bottom, the individual craters are called Minucia, which is 13 miles (21.5 km) wide; Calpurnia, 30 miles (50 km) wide; and Marcia, 36 miles (58 km) wide. The Dawn spacecraft’s instruments are studying the surface composition of Vesta, with the objective of matching meteorites to specific areas on the asteroid. One likely source is the south-polar mountain, which rises 13 miles (22 km) within the Rheasilvia impact basin.

ASTEROIDS MAIN-BELT ASTEROID

1 Ceres AVERAGE DISTANCE TO SUN

257 million miles

(414 million km) 4.60 years

ORBITAL PERIOD

ROTATION PERIOD DIAMETER

9.08 hours

590 miles (950 km)

DATE OF DISCOVERY

January 1, 1801

Ceres was discovered by accident in 1801 by Giuseppe Piazzi, the director of the Palermo Observatory in Italy, while he was compiling a catalog of fixed stars (see panel, right). One of the “stars” had moved during the night, and this turned out to be the first known asteroid, Ceres. Some 100 years before, Johannes Kepler (see p.68) had suspected that there was a “missing” planet in the gap between the orbits

of Mars and Jupiter (see pp.170–71). By 1800, some of Europe’s leading astronomers had started to look for objects in this gap, and Piazzi made the first discovery. About a year later, a German doctor and astronomer, Heinrich Olbers, was observing the path of Ceres in an attempt to produce a more accurate estimate of its orbital parameters when he discovered a second asteroid. This was given the number 2 and named Pallas. The orbits of Ceres and Pallas were found to cross, and Olbers concluded that they were fragments of a planet that had broken up. As the century progressed, more and more asteroids were discovered that were smaller and fainter than the first two.

Using spectroscopes to analyze the light reflected from their surfaces, astronomers found that asteroids had different colors, due to different compositions, and this led to the establishment of a classification system (see p.170). Ceres was classified as a carbonaceous, or C-type, asteroid. In 2006, the new category of dwarf planets was introduced to describe objects that are rounded in shape but have not swept their orbits clear of other bodies (see p.209). Ceres was placed in this category. However, it remains the largest member of the asteroid belt, so it can be said to have a dual identity as both a dwarf planet and an asteroid. In 2015 Ceres is due to be visited by a NASA space probe called Dawn, which will fly there after having studied Vesta (see opposite).

175

EXPLORING SPACE

PIAZZI’S TELESCOPE Known as the Palermo Circle, this telescope was made between 1787 and 1789 by Jesse Ramsden of London, England, the greatest European instrument maker of the 18th century. Its lens has an aperture of 3 in (75mm). The circular altitude scale and the horizontal azimuth scale are both read using microscopes. In its day, it was the most southerly European telescope, being on top of the Royal Palace in Palermo, Sicily. While measuring star positions with this telescope, Piazzi discovered the first asteroid, Ceres.

CERES IN THE HYADES

When viewed from Earth, Ceres, highlighted here in the Hyades star cluster in the constellation Taurus, moves nearly a quarter of a degree (half a Moon diameter) per day against the background stars. Hence its motion can easily be noticed from night to night, although a pair of binoculars or a small telescope is needed to see it.

NEAR-EARTH ASTEROID

25143 Itokawa ttgt(198 million km) ORBITAL PERIOD

1.52 years

ROTATION PERIOD LENGTH

12.1 hours

0.34 miles (0.54 km)

DATE OF DISCOVERY

September 26, 1998

Itokawa is a small, irregularly shaped asteroid of the type known as a “rubble pile,” meaning that it is not a solid, coherent body. The Japan Aerospace Exploration Agency (JAXA) chose it as the target for a sample-collection mission called EXPLORING SPACE

THE HAYABUSA MISSION

ASTEROID APPROACH

An artist’s impression shows the Japanese space probe Hayabusa approaching asteroid Itokawa in November 2005.

across. Large impacts broke the asteroid into smaller pieces, which then gently reassembled to form the low-density rubble-pile structure that we see today. Rocks that are up to 165 ft (50 m) wide are dotted over Itokawa’s surface, while the narrow neck near the middle is smoother and covered with dust. In November 2005, the Hayabusa space probe gently touched down on the smooth part. It collected numerous microscopic particles of the asteroid’s dust, which it brought back to Earth. The sample return capsule blazed through the Earth’s atmosphere to land at Woomera, Australia, in June 2010. The capsule was retrieved and opened under sterile conditions in a laboratory in Japan. The asteroid’s surface rocks proved to be rich in the mineral olivine, similar to common types of chondrite meteorites.

ELONGATED ASTEROID

This image of Itokawa was taken by the Hayabusa probe, which landed in the smooth area near the middle to collect dust samples. The asteroid lacks obvious impact craters, in contrast to most others visited by spacecraft.

ROUGH SURFACE

Large rocks can be seen strewn over Itokawa’s surface in this close-up. These rocks are probably fragments of an earlier breakup of the asteroid that have since collected together again.

TH E S OL A R S Y S TE M

Hayabusa was a Japanese probe sent to rendezvous with, and bring back samples from, the near-Earth asteroid Itokawa. Hayabusa is the Japanese name for the peregrine falcon. It was intended to swoop down on the asteroid like a hawk, to take samples, and then return them to Earth. It spent 30 minutes on the asteroid’s surface before taking off again with dust samples.

Hayabusa, which the agency launched in May 2003 (see panel, below). At the time of launch, the asteroid bore only the reference number 1998SF36, but it was named in honor of Hideo Itokawa (1912–99), known as the father of Japanese rocketry, while the probe was on its way. The Hayabusa probe reached Itokawa in September 2005 and spent two months surveying the asteroid before attempting a landing. The asteroid’s gherkinlike shape, 1,110 ft (540 m) long and 690 ft (210 m) across at its narrowest, gives it the appearance of two separate masses stuck together. Astronomers think that Itokawa was once much bigger, perhaps up to 12 miles (20 km)

176

ASTEROIDS NEAR-EARTH ASTEROID

433 Eros AVERAGE DISTANCE TO SUN

136 million miles

(218 million km) ORBITAL PERIOD

1.76 years

ROTATION PERIOD LENGTH

5.27 hours

19.25 miles (31 km)

DATE OF DISCOVERY

August 13, 1898

TH E S O LA R S YS TEM

Lying in near-Earth orbit, outside the Main Belt, Eros is usually closer to the Sun than to Mars (see p.170). Its orbit also brings it close to Earth; COMPUTER MODELS at the last close approach, in 1975, The gravity on Eros is about 1/2,000th of that Eros came within 14 million miles on Earth, but varies by nearly a factor of two (22 million km) of the planet. The from place to place. The colors in this image orbit is unstable, and Eros has a onerepresent the rate at which a rock would roll in-ten chance of hitting either Earth downhill. It would roll fastest in the red areas, or Mars in the next million years. In and it wouldn’t move at all in the blue areas. 1960, Eros was detected by radar, and infrared measurements taken in 160,000 images were the 1970s indicated that recorded. They revealed the surface was not just an irregularly shaped bare rock but was body, which had heavily covered by a thermally cratered 2-billion-yearinsulating blanket of old areas lying next to dust and rock fragments. relatively smooth Eros was the first regions. Even though asteroid to be orbited the gravitational field is by a spacecraft and the very small, several CLOSING IN first to be landed on. thousand boulders larger NEAR Shoemaker took this It was chosen for image from a height of 3,770 ft than 50 ft (15 m) across close study because have fallen back to the (1,150 m) shortly before it it is big and nearby. surface after being touched down on Eros. On February 14, ejected by impacts, and 2000, the Near Earth Asteroid some surface dust has rolled down the Rendezvous (NEAR) spacecraft slopes to form sand dunes a few yards (renamed NEAR Shoemaker in (meters) deep. Laser measurements of March 2000) went into orbit around the NEAR–Eros distance as the spaceEros. It landed 363 days later. About craft orbited have not only produced an accurate map of the asteroid’s shape but also indicated that the interior is ROCK AND REGOLITH nearly uniform, with a density about Some of the rocks the same as that of Earth’s crust. Eros and regolith on Eros’s is not a pile of rubble like Mathilde; surface have a red it is a single, solid lump of rock. coloring. The longer The spacecraft’s gamma-ray their exposure to spectrometer worked for two weeks minor impacts and after touchdown. Eros was found to the solar wind, the be silicate-rich and highly reflective. redder they appear.

THE SADDLE

Four images have been combined to produce this view of the “saddle” region at the south of the asteroid. This 6-mile- (10-km-) wide scoop, which has been named Himeros, is relatively boulder-free, unlike the region at the lower right of the frame.

177

Eros is elongated and irregular—like a cosmic potato. Its shape is the result of a series of vigorous collisions. Large impacting objects have created craters all over Eros, and dust impacts have sandblasted the surface, smoothing it off. This view of Eros was taken looking down on the north polar region.

TH E S OL A R S Y S TE M

THE COSMIC POTATO

178

JUPITER

JUPITER JUP ITER IS THE LARGEST AND M OST M ASSIVE

of all the planets. It has almost 2.5 times the mass of the other 68–69 Planetary motion eight planets combined, and over 1,300 Earths 100–101 The history of the solar system could fit inside it. Jupiter bears the name of 103 Gas giants the most important of all the Roman gods (known as Zeus in Greek mythology). The planet has the largest family of moons in the solar system, its members named after Jupiter’s lovers, descendants, and attendants. 38–39 Gravity, motion, and orbits

ORBIT Jupiter is the fifth planet from the Sun. It lies approximately five times as far away as Earth, but its distance from the Sun is not constant. Its orbit is elliptical and there is a difference of 47.3 million miles (76.1 million km) between its aphelion and perihelion distances. Jupiter’s spin axis tilts by 3.1°, and this means that neither of the planet’s hemispheres point markedly toward or away from the Sun as it moves around its orbit. Consequently, Jupiter does not have obvious seasons. The planet spins quickly around its axis, more quickly than any other planet. Its rapid spin throws material in its equatorial region outward. The result is a bulging equator and a slightly squashed appearance. spins on its axis once every 9.93 hours

axis tilts from the vertical by 3.1°

APHELION 507.1 million miles (816.6 million km)

PERIHELION 459.9 million miles (740.5 million km) Sun

SPIN AND ORBIT Jupiter orbits the Sun in 11.86 Earth years

T HE S O LA R S Y S TE M

STRUCTURE

The rotation period of just less than 10 hours and orbital period of nearly 12 Earth years means that there are about 10,500 Jovian days in one Jovian year.

Although it is the most massive planet (318 times the mass of the Earth), Jupiter’s great size means that its density is low. Its composition is more like the Sun’s than any other planet in the solar system. Jupiter’s hydrogen and helium is in a gaseous form in the outer part of the planet, where the temperature is about -166˚F (-110˚C). Closer to the center, the pressure, density, and temperature increase. The state of the hydrogen and helium changes accordingly. By about 4,350 miles (7,000 km) deep, at about 3,600˚F (2,000˚C), hydrogen acts more like a liquid than a gas. By 8,700 miles (14,000 km), at about 9,000˚F (5,000˚C), hydrogen has compacted to metallic hydrogen and acts like a molten metal. Deep inside, at a depth of about 37,260 miles (60,000 km), is a solid core of rock, metal, and hydrogen compounds. The core is small compared to Jupiter’s great size but is about 10 times the mass of Earth.

gaseous hydrogen and helium

outer layer of liquid hydrogen and helium

inner layer of metallic hydrogen

core of rock, metal, and hydrogen compounds

JUPITER INTERIOR

At the heart of Jupiter lies a relatively small, dense, and probably solid core. The core is surrounded by layers of metallic, liquid, and gaseous material, which is predominantly hydrogen.

JUPITER GAS GIANT

179

JUPITER PROFILE

Jupiter’s surface is not solid. Each light or dark band and every big or small swirl or spot is a part of the planet’s cloudy atmosphere.

AVERAGE DISTANCE FROM THE SUN

ROTATION PERIOD

483.6 million miles (778.3 million km)

9.93 hours

CLOUDTOP TEMPERATURE

ORBITAL PERIOD (LENGTH OF YEAR)

11.86 Earth years

–160ºF (–110ºC) DIAMETER

88,846 miles (142,984 km)

MASS (EARTH = 1)

318

VOLUME (EARTH = 1)

1,321

CLOUD-TOP GRAVITY (EARTH = 1)

NUMBER OF MOONS

64

SIZE COMPARISON EARTH

OBSERVATION

2.53

JUPITER

Jupiter is bright and easy to spot. It has a maximum magnitude of –2.9. Even at its faintest it is brighter than Sirius, the brightest star in the sky. Jupiter is best seen at opposition, which occurs once every 13 months.

MAGNETIC FIELD Jupiter has a magnetic field—it is as if the planet had a large bar magnet deep inside it. The field is generated by electric currents within the thick layer of metallic hydrogen, and the AURORA axis joining the magnetic poles is This striking electric-blue tilted at about 11° to the spin axis. aurora centered on Jupiter’s The field is stronger than that of north magnetic pole was any other planet. It is about 20,000 imaged by the Hubble Space times stronger than Earth’s magnetic Telescope in 1998. field and has great influence on the volume of space surrounding Jupiter. Solar wind particles (see p.107) streaming from the Sun plow into the field. They are slowed down and rerouted to spiral along the field’s magnetic lines of force. Some particles enter Jupiter’s upper atmosphere around its magnetic poles. They collide with the atmospheric gases, which radiate and produce aurorae. Other charged particles (plasma) are trapped and form a disklike sheet around Jupiter’s magnetic equator. Electric currents flow within this sheet. Highenergy particles are trapped and form radiation belts, similar to, but much more intense than, the Van Allen belts round Earth (see p.125). Jupiter’s magnetic field is shaped by the solar wind, forming a vast region called the magnetosphere. Its size varies with changes in pressure of the solar wind, but the tail is thought to have a length of about 370 million miles (600 million km). axis of rotation solar wind deflected

direction of magnetic force lines

plasma sheet axis of magnetic field northern horn

bow shock southern horn

JUPITER’S MAGNETOSPHERE

Jupiter’s magnetosphere—the bubblelike region around Jupiter dominated by the planet’s magnetic field—is enormous; it is one thousand times the volume of the Sun, and its tail stretches away from the planet as far as Saturn’s orbit. This slice through the magnetosphere reveals its structure.

tail turbulence magnetic equatorial plane radiation belt solar wind deflected

magnetosheath

T HE SO LA R S Y S TE M

solar wind

180

JUPITER

ATMOSPHERE

north polar region

rising air forms zone of white ammonia clouds

Jupiter’s atmosphere is dominated by hydrogen, with helium being the next most common gas. The rest is made up of simple hydrogen compounds— such as methane, ammonia, and water—and more complex ones such as ethane, acetylene, and propane. It is descending these compounds that condense cooler air to form the different-colored clouds of the upper atmosphere westward air and help give Jupiter its distinctive flow banded appearance. The temperature of the atmosphere increases toward the planet’s interior. As gases condense at different temperatures, different types of clouds form at specific altitudes. All the while, the gas in Jupiter’s equatorial region is heated by the Sun, and this water vapor at rises and moves toward the polar regions. Cooler lower altitude air flows from the polar regions at a lower altitude to take its place, creating in effect a large circulation cell. This hemisphere-wide circulation transfer would be straightforward if Jupiter were stationary. It is not—it rotates, and speedily at that, and a force known as the Coriolis effect (see p.126) deflects the north–south flow into an east–west flow. As a result, the large circulation cell is split into many smaller cells of rising and falling air. These are seen on Jupiter’s surface as alternating bands of color. Jupiter’s white bands of cool rising air are called zones. The red-brown bands of warmer falling air are known as belts.

North Temperate Belt

storm system North Tropical Zone (includes the paler bands above and below)

North Equatorial Belt

Equatorial Zone

South Equatorial Belt

Great Red Spot South Tropical Zone (includes the paler band above)

South Temperate Belt

air flow diverted to the east by the Coriolis effect

red-brown cloud belt

CLOUD FORMATION

Clouds of different compounds form at different altitudes in the atmosphere. Convection currents move the mixture of gas upward. Water is first to reach the altitude where it is cool enough to condense to form clouds. Higher up, where it is cooler, red-brown ammonium hydrosulfide clouds form, and highest of all, where it is coolest, are the white ammonia clouds.

BELTS AND ZONES

This mosaic of images taken by the Cassini spacecraft at a distance of 6 million miles (10 million km) shows the colorful bands of Jupiter’s upper atmosphere as they would appear to the human eye.

hydrogen (89.8%)

COMPOSITION OF ATMOSPHERE

helium with traces of methane and ammonia (10.2%)

Hydrogen dominates, but it is the trace compounds that color Jupiter’s upper atmosphere.

south polar region

MOONS

TRIPLE ECLIPSE

Jupiter has over 60 known moons, over two-thirds of which have been discovered since January 2000. Only 50 of the moons have been given names, and several have yet to have their orbit confirmed. The recent discoveries are typically irregularly shaped rocky bodies a few miles across, and are thought to be captured asteroids. By contrast, Jupiter’s four largest moons are spherical bodies that were formed at the same time as Jupiter. Collectively known as the Galilean Moons (see p.182), they were the first moons to be discovered after Earth’s Moon. As they orbit Jupiter, passing between it and the Sun, their shadows sweep across the planetary surface; from within the shadow, the Sun appears eclipsed. A triple eclipse happens just once or twice a decade.

Three shadows were cast onto Jupiter’s surface on March 28, 2004 as its three largest moons passed between the planet and the Sun. Io is the white circle in the center, its shadow to its left. Ganymede is the blue circle at upper right, and its shadow lies on Jupiter’s left edge. Callisto’s shadow is on the upper-right edge, but the moon itself is out of view, to the right of the planet. +

Lysithea 163.9

Elara 164.2

JUPITER’S MOONS

TH E S O LA R S YS TEM

Europa 9.4

Callisto 26.3

Himalia 160.3

Themisto 105.0

Leda 156.2

Ganymede 15.0

25

1 radius +

Adrastea 1.80

50

75

125

100 +

Io 5.91

S/2003 J9 313.9

Thebe 3.11 Metis 1.79

Kallichore 313.3

Amalthea 2.54

Scale in radii of Jupiter

1 1 radius = 44,397 miles (71,492 km)

Moons are not to scale and increase in size for magnification purposes only

150

175

2

S/2003 J19 318.9 Arche 320.7

JUPITER

181

WEATHER Jupiter has no notable seasons, and the planet’s THE GREAT RED SPOT This giant storm, which is temperature is virtually uniform. Its polar bigger than Earth, is constantly regions have temperatures similar to those changing its size, shape, and of its equatorial regions because of internal color. It rotates counterclockwise every six to seven days. heating. Jupiter radiates about 1.7 times more heat than it absorbs from the Sun. The excess is infrared heat left from when the planet was formed. Most of Jupiter’s weather occurs in the part of its atmosphere that contains its distinct white and red-brown cloud layers and is dominated by clouds, winds, and storms. The rising warm air and descending cool air within the atmosphere produce winds that are channeled around the planet, both to the east and west, by Jupiter’s fast spin. The wind speed changes with latitude; winds within the equatorial region are particularly strong and reach speeds in excess of 250 mph (400 km/h). The solar and infrared heat, the wind, and Jupiter’s spin combine to produce regions of turbulent motion, including circular and oval cloud structures, which are giant storms. The smallest of these storms are like the largest hurricanes on Earth. They can be relatively shortlived and last for just days at a time, RED TRIO but others endure for years. Jupiter’s In 2008, the Great Red Spot was most prominent feature, the Great Red accompanied by two smaller red spots. Spot, is an enormous high-pressure One, called Red Spot Jr., had formed in storm that may have first been sighted 2006. The third, and smallest, one was from Earth over 340 years ago. later absorbed by the Great Red Spot.

RINGS Jupiter’s ring system was revealed for the first time in an image taken by Voyager 1 in 1979. It is a thin, faint system made of dust-sized particles knocked off Jupiter’s four inner moons. The system consists of three parts. The main ring is flat and is about 4,350 miles (7,000 km) wide and less than 18 miles (30 km) thick. Outside this is the flat gossamer ring, which is 528,000 miles (850,000 km) wide and stretches beyond Amalthea to Thebe’s orbit. On the inside edge of the main ring is the 12,400-mile- (20,000 km-) thick doughnut-shaped halo. Its tiny dust grains reach down to Jupiter’s cloudtops.

EXPLORING SPACE

DEATH OF A COMET Comet Shoemaker–Levy 9 was discovered orbiting Jupiter in March 1993. Unusually, it wasn’t a single object but a string of 22 cometary chunks. Astronomers calculated that in July 1992 the comet had been torn apart by Jupiter’s gravitational pull, and they realized that the fragments were on a

collision course with the planet. In July 1994, the fragments hurtled into Jupiter’s atmosphere, each impact being followed by an erupting fireball of hot gas. HEADING FOR DESTRUCTION

Shoemaker–Levy 9 fragments orbit Jupiter in May 1994, just weeks before they slammed into the planet’s atmosphere. A cloud of gas and dust surrounds each fragment.

JUPITER’S MAIN RING +

Helike 293.5

Harpalyke 295.3

Thelxinoe 296.5

Thyone 298.1

Hermippe 297.2

Euanthe 294 S/2003 J16 293.7

S/2003 J3 256.5

225

200

Euporie 271.2

S/2003 J18 289.5

275

250

Pasithee 322.1

Ananke 297.7

S/2003 J15 307.7

Mneme 288.1

S/2003 J12 265.8 S/2010 J2 284.0

Iocaste 297.5

Herse 307.7

325

300 Kalyke 329.8

S/2003 J2 399.6

Kore 349.7

Sponde 333

375

350 Cyllene 335.7

S/2003 J5 336.8

400 S/2003 J10 339.2

425 Eukelade 343.5

Megaclite 333 Pasiphae 330.4

+

Chaldene 324.2 Aitne 324.5 Kale 323.4

Eurydome 324.8

Isonoe 324.8

Erinome 325.6 S/2003 J4 325.4

Aoede 333

Taygete 326.7 S/2010 J1 326.1

Carme 327.3

Sinope 334.9

S/2003 J23 329.4

Callirhoe 337.1

Autonoe 337.4

Hegemone 342.8

TH E S O LA R S Y S TE M

Carpo 239.2

Orthosie 296.1

Praxidike 295.8

Jupiter’s main ring was imaged by Galileo with the Sun behind the planet. From this position, small particles within the ring and in Jupiter’s upper atmosphere stand out. The halo and gossamer ring are revealed only if the main ring is overexposed.

182

JUPITER’S MOONS

GALILEAN MOON

Jupiter’s moons fall into three categories: the four inner moons; the four large Galilean moons; and the rest, the small outer moons. The inner and Galilean moons orbit in the usual direction—that is, the same direction as Jupiter’s spin (counterclockwise viewed from above the north pole). Most of the outer moons travel in the opposite direction, SO NEAR AND YET SO FAR Io, one of the largest of Jupiter’s suggesting that they originated from an 64 moons, appears close to its planet, but the two are almost three asteroid that fragmented after it was times the diameter of Jupiter apart. captured by Jupiter’s gravitational field. INNER MOON

INNER MOON

Metis

Adrastea

DISTANCE FROM JUPITER ORBITAL PERIOD DIAMETER

INNER MOON

79,460 miles (127,960 km)

6 hours 58 minutes

25 miles (40 km)

Metis, the closest moon to Jupiter, is irregular in shape and lies within the planet’s main ring. It was discovered on March 4, 1979 by the Voyager 1 probe. Metis is named after the first wife of Zeus, who was swallowed by him when she became pregnant.

JUPITER’S CLOSEST MOON

DISTANCE FROM JUPITER ORBITAL PERIOD LENGTH

Thebe 80,100 miles (128,980 km)

7 hours 9 minutes

16 miles (26 km)

The small, irregularly shaped Adrastea is the second moon out from Jupiter and lies within its main ADRASTEA ring. For each orbit of Jupiter, Adrastea spins once on its axis, so the same side of the moon always faces the planet. This synchronous rotation is also exhibited by Adrastea’s three closest neighbors, Metis, Amalthea, and Thebe. Adrastea was discovered by Voyager 2 in July 1979, and is named after a nymph of Crete into whose care, according to Greek mythology, the infant Zeus was entrusted.

INNER MOON

ORBITAL PERIOD

T HE S O LA R S Y S TE M

LENGTH

ORBITAL PERIOD LENGTH

68 miles (110 km)

The most distant of the inner moons, Thebe is named after an Egyptian king’s daughter who was a granddaughter of Io. The moon, which was discovered on March 5, 1979 by Voyager 1, lies within the outer part of the Gossamer Ring (see p.181).

THEBE SHOWING IMPACT CRATER

Themisto 112,590 miles (181,300 km)

DISTANCE FROM JUPITER

4.66 million miles

(7.5 million km)

11 hours 46 minutes

ORBITAL PERIOD

163 miles (262 km)

DIAMETER

The largest of Jupiter’s inner moons and the third from the planet, Amalthea is named after the nurse of newborn Zeus. The irregularly shaped moon lies within the Gossamer Ring and is believed to be a source of ring material. Meteoroids from outside the Jovian system collide with Amalthea and the other inner moons, chipping off flecks of dust, which then become part of the ring system. Amalthea’s unexpected discovery on September 9, 1892, over 280 years after the four much larger Galilean moons had been discovered, was headline news.

130 Earth days

5 miles (8 km)

In November 2000, astronomers at the Mauna Kea Observatory, Hawaii, carried out a systematic search for new moons and identified 11 small moons. Observations recorded on subsequent nights revealed that one of the 11, since named Themisto, was a moon that had been discovered by American astronomer Charles Kowal on September 30, 1975, but then lost.

BARNARD’S TELESCOPE

Amalthea was the last of Jupiter’s moons to be discovered by direct visual observation (as opposed to photography). Its discoverer, American Edward Barnard, used a 36-in (91-cm) refractor telescope, which is now preserved at the Lick Observatory in California. BATTERED SURFACE

The circular feature in this image is Pan, which, with a diameter of about 56 miles (90 km), is the largest impact crater on Amalthea. The bright spot below Pan is associated with another, smaller crater, Gaea (bottom).

DISTANCE FROM JUPITER ORBITAL PERIOD DIAMETER

416,630 miles (670,900 km)

3.55 Earth days

1,939 miles (3,122 km)

Europa is an ice-covered ball of rock, which has been studied for about 400 years but whose intriguing nature was only fully revealed once the Galileo space probe started its study in 1996. The probe was named after the Italian scientist Galileo Galilei, who observed Europa, along with the three other moons that collectively bear his name, in January 1610, from Padua, Italy. The German astronomer Simon Marius (1573–1624) is believed to

137,800 miles (221,900 km)

16 hours 5 minutes

OUTER MOON

Amalthea DISTANCE FROM JUPITER

DISTANCE FROM JUPITER

Europa

THEMISTO REDISCOVERED

This digital image is one of a series that shows Themisto (highlighted) and its changing position against the background stars, which led to its rediscovery in November 2000.

DAYTIME TEMPERATURE

Infrared observations reveal heat radiation from Europa’s surface at midday. Temperatures at the equator (shown here as yellow) reach about –225˚F (–140˚C). Farther away from the equator, the surface temperatures are even lower.

JUPITER have observed the moons first, but it was Galileo who published his findings and brought the moons to the attention of the scientific and wider community. Jupiter’s fourth-largest satellite is a fascinating world. It is a little smaller than Earth’s Moon, but much brighter, since its icy surface reflects five times as much light. A liquid sea may lie below Europa’s water-ice crust, which is just tens of miles thick. This watery layer, which is estimated to be 50–105 miles (80–170 km) deep and to contain more liquid than Earth’s oceans combined, could be a haven for life. Below lies a rocky mantle surrounding a metallic core. fractures in crust

183

EXPLORING SPACE

KEEP EUROPA CLEAN

PWYLL CRATER

OVERHEAD VIEW

The surface appears to be geologically young and consists of smooth ice plains, disrupted terrain, and regions crisscrossed by dark linear structures that can be thousands of miles long. The mottled appearance of the disrupted terrain comes from Pwyll Crater

IMAGE OF THE FAR SIDE

This is how the far side of Europa would appear to the human eye. Bright plains in the polar areas (top and bottom) sandwich a darker, disrupted region of the crust.

TERRAIN MODEL

This three-dimensional model of the 16-mile(26-km-) wide Pwyll Crater (above) was made by combining images (see example, left) taken from different angles and then applying color. Unusually, the crater floor (blue) is the same height as the moon’s surface, and the central peak (red) is much higher than the crater’s rim.

crust that has broken up and floated into new positions. Round or oblong, city-sized dark spots freckle the surface. Known as lenticulae, these form as large globules of warm and slushy ice push up from underneath and briefly melt the surface ice. Exactly how the dark lines formed is unclear, but volcanically heated water and ice and other kinds of tectonic activity were involved. Tidal forces fractured the crust, and liquid or icy water erupted through the crack to freeze almost instantly on the surface. In Greek myth, Europa was the girl who was seduced by Zeus in the form of a white bull and carried off to Crete.

After a six-year journey from Earth, the Galileo space probe spent eight years studying the Jovian system and made 11 close flybys of Europa. The decision was made to destroy the probe because NASA wanted to avoid an impact with Europa and the potential contamination of its subsurface ocean, which could possibly harbor life. With little fuel left, Galileo was put on a collision course with Jupiter. The probe disintegrated in the planet’s atmosphere on September 21, 2003. GALILEO

high-gain antenna

nuclear-powered generators provided electricity

This area of Europa’s northern hemisphere shows features typical of the moon’s icy surface. Brown grooves and ridges slice across a blue-gray water-ice surface freckled by lenticulae. The colors in this mosaic of images taken by Galileo have been enhanced to reveal detail.

TH E S OL A R S Y S TE M

ICY SURFACE

184

JUPITER GALILEAN MOON

Io DISTANCE FROM JUPITER ORBITAL PERIOD

TH E S O LA R S YS TEM

DIAMETER

261,800 miles (421,600 km)

1.77 Earth days

2,262 miles (3,643 km)

Io is a little larger and denser than Earth’s Moon, and orbits Jupiter at a distance only slightly greater than the Moon’s from Earth. But there the similarities end. Io is a highly colored world of volcanic pits, calderas and vents, lava flows, and high-reaching plumes. The moon’s nature was revealed first by the two Voyager probes and then more fully explored by the Galileo mission. Prior to Voyager 1’s arrival in March 1979, scientists expected to find a cold, impact-cratered moon. Instead, it found the most volcanic body in the solar system. Io has a thin silicate crust that surrounds a molten silicate layer. Below this lies a comparatively large iron-rich core that extends about halfway to the surface. Io orbits Jupiter quickly, every 42.5 hours or so. As it orbits, it is subjected to the strong gravitational pull of Jupiter on one side and the lesser pull of Europa on the other. Io’s surface flexes as a ring of sulfurconsequence of the dioxide snow varying strength and direction of the pull it experiences. The flexing is accompanied by friction, which produces the heat that keeps part of Io’s interior molten. It is this material that erupts through the surface and constantly renews it. The evidence of such volcanism is seen all over Io. Over 80 major active volcanic sites and more than 300 vents have been identified. Features known as plumes are also found at the surface; these fast-moving and longlived columns of cold gas Culann Patera and frost grains are more like geysers than volcanic explosions. They are created as superheated sulfur dioxide shoots through fractures in Io’s crust. The material in the plumes falls slowly back to the surface as snow, and leaves circular or oval frost deposits. Plume material also spreads into space surrounding Io and supplies a doughnut-shaped body of material that has formed along Io’s orbital path. Temperatures TOHIL MONS

Non-volcanic mountains are also found on Io. Here, the sunlit peak of the 185-mile- (300-km-) wide Tohil Mons rises 3.4 miles (5.4 km) above Io’s surface.

JUPITERSHINE

Sunlight reflected off Jupiter illuminates Io’s western side. The eastern side is in shadow except for a burst of light beyond the limb where the plume of the volcano Prometheus is lit. The yellowish sky is produced by sodium atoms surrounding Io scattering the sunlight.

Tohil Mons In this color-enhanced Galileo image, the dark spots on Io’s surface are active volcanic centers. The dark eruptive area of Prometheus at center left is encircled by a pale yellow ring of sulfur-dioxide snow deposited by the volcano’s plume. VOLCANIC ACTIVITY

at the volcanic hot spots can be over 2,240˚F (1,230˚C), the highest surface temperatures in the solar system outside the Sun. Elsewhere the surface is cold, reaching just -244˚F (-153˚C). Simon Marius (see p.182) suggested the names of the Galilean moons. Io is named after one of Zeus’s loves, whom he changed into a cow to hide her from his jealous wife. Hera was not fooled and sent a gadfly to torment Io forever. Other surface features are named after people and places from the Io myth or from Dante’s Inferno, or after fire, sun, volcano and thunder gods, goddesses, and heroes.

CULANN PATERA

Colorful lava flows stream away from the irregularly shaped greenfloored volcanic crater of Culann Patera (right of center). The reasons for the varied colors are uncertain. The diffuse red material is thought to be a compound of sulfur deposited from a plume of gas. The green deposits may be formed when sulfur-rich material coats warm silicate lava.

185

In this Voyager 1 image from 1979, a 185-mile(300-km-) high plume rises above Pele, the first active volcanic site discovered on Io. Io’s low gravity allows the gas to rise high above the moon before falling back to the surface. Named after the Hawaiian volcano goddess, Pele was still active almost 20 years later.

TH E S OL A R S Y S TE M

PELE ERUPTS

186

JUPITER GANYMEDE

In this color-enhanced view, frosts at polar latitudes appear pale mauve. A distinct, dark area is called a regio, and Nicholson Regio, visible lower left, is the third-largest, at 2,425 miles (3,900 km) across.

GALILEAN MOON

Ganymede DISTANCE FROM JUPITER

664,470 miles

(1.07 million km) ORBITAL PERIOD

THE SOLAR SYSTEM

DIAMETER

7.15 Earth days

3,267 miles (5,262 km)

Ganymede is the largest moon in the solar system, bigger than both Pluto and Mercury, and three-quarters the size of Mars. It is named after the beautiful young boy in Greek myth who was taken to Olympus by Zeus and became cupbearer to the gods.

Ganymede was formed from a 60:40 mix of rock and ice. This differentiated, and today the moon has an iron-rich core surrounded by a lower mantle of rock, an upper mantle of ice, and an icy crust of contrasting dark and bright areas. The dark terrain is pockmarked by impact craters, suggesting that it is an older surface. Circular bright areas termed palimpsests are the smoothed-out and filled-in remains of craters formed on INFRARED MAPPING

The infrared image on the left, taken by Galileo, locates surface water-ice—the brighter the shading, the greater the amount. The colors of the right-hand image indicate the location of minerals (red) and the size of ice grains (shades of blue).

URUK SULCUS

This computer-generated perspective shows the area Uruk Sulcus, named after a Babylonian city. Icy material can be seen on the crests of the parallel ridges. Sulcus is the term for the grooved and ridged regions of bright terrain.

the icy surface in the distant past. The dark terrain is also characterized by long depressions about 4 miles (7 km) wide, called furrows. These may have formed as subsurface ice flowed into recently formed craters and material dragged across the surface created the bow-shaped troughs. The bright terrain, which is rich in water ice

with patches of carbon-dioxide ice, is generally smoother and marked by fewer craters. It is crisscrossed by ridges and grooves produced by the tectonic stretching of the moon’s surface. SIPPAR SULCUS

This depression within Sippar Sulcus appears to be an old caldera (a volcano’s collapsed underground reservoir) containing frozen lava.

JUPITER TINDR CRATER

GALILEAN MOON

Callisto DISTANCE FROM JUPITER

1.17 million miles

(1.88 million km) ORBITAL PERIOD DIAMETER

187

16.69 Earth days

2,994 miles (4,821 km)

The partial collapse of the rim of this 47-mile(76-km-) wide crater and its pitted floor is probably the result of erosion by ice.

The most distant, second-largest, and darkest of the Galilean moons, Callisto is still brighter than Earth’s Moon since its surface contains ice that reflects sunlight. Callisto has undergone little internal change since its formation. Its original mix of rock and ice is only partly differentiated, so that the moon is rockier toward its center and icier

toward its crust. The surface, scarred by craters and multi-ringed structures created by meteorite impacts, bears few signs of geological activity. Callisto does not appear to have been shaped by plate tectonics or cryovolcanism, where ice behaves like volcanic lava, although the ice has eroded the rock in places, causing crater rims to be worn away and sometimes collapse.

dark areas lack ice

SCARRED SURFACE

This is the only complete global color image of Callisto obtained by Galileo. The surface is uniformly cratered, and the bright impact scars are easily visible against its otherwise dark, smooth surface. ice on crater rim and floor shines brightly

The craters are named after heroes and heroines of northern myths, and the large, ringed features, such as the Valhalla Basin (see below), after homes of the gods or heroes. About 1,600 miles (2,600 km) across, the Valhalla Basin was probably formed by a large meteorite strike early in Callisto’s history, which fractured the moon’s cold, brittle crust, allowing ice that was previously below the surface to flood the impact site.

VALHALLA REGION

This photograph of part of the Valhalla Basin, lit by sunlight streaming in from the left, shows a 6-mile- (10-km-) wide fault scarp, part of Valhalla’s ring system. The smallest craters visible are about 510 ft (155 m) across. MYTHS AND STORIES

CALLISTO Callisto was a beautiful follower of the huntress Artemis, who was seduced by Zeus and bore him a son. According to one myth, Zeus’s jealous wife, Hera, turned Callisto into a bear. One day, Callisto came across her son, Arcas, now grown. Fearful for his life, Arcas was only stopped from killing Callisto by Zeus, who raised a whirlwind that carried the pair up into the sky. Callisto became the constellation Ursa Major and Arcas formed Boötes.

The multi-ringed Valhalla Basin dominates Callisto’s surface. The bright, ice-covered central zone is about 370 miles (600 km) across. It is surrounded by rings, which are troughs about 30 miles (50 km) apart.

TH E S OL A R S Y S TE M

MULTI-RING BASIN

188

SATURN

SATURN SATURN IS THE SECOND-LARGEST PLANET

and the sixth from the Sun—it is the most distant planet normally visible 68–69 Planetary motion to the naked eye. A huge ball of gas and liquid, Saturn has 100–101 The history of the solar system a bulging equator and an internal energy source. With a 102–103 The family of the Sun composition dominated by hydrogen, it is the least dense of all the planets. A spectacular system of rings encircles the planet itself, and it also has a large family of moons. 38–39 Gravity, motion, and orbits

NORTHERN SPRING EQUINOX

ORBIT

spins on its axis every 10.66 hours

Saturn takes 29.46 Earth years to NORTHERN SUMMER SOLSTICE complete one orbit of the Sun. It is tilted to its orbital plane by 26.7°, a little more than Earth’s axial tilt. This means that as Saturn moves APHELION 938 million along its orbit, the north and south miles (1.51 poles take turns pointing toward billion km) the Sun. The changing orientation of Saturn to the Sun is seen from Earth by the apparent opening and closing of the planet’s ring system. The rings are seen edge-on, for example, at the start of an orbital period. Then an increasing portion of the rings is seen from above as the North Pole tips toward the Sun. The rings slowly close up and disappear from view as the North Pole starts to tip away until, 14.73 Earth years (half an orbit) later, they appear edge-on again. Now the South Pole tips sunward and the rings are seen increasingly from below. They close up once again as the South Pole turns away, until they are seen edge-on once more, as the orbit is completed. The strength of the Sun at Saturn is only about 1 percent of that received on Earth, but it is enough to generate seasonal smog. Saturn is at perihelion at the time the South Pole is facing the Sun.

axis tilts from the vertical by 26.7° NORTHERN WINTER SOLSTICE

PERIHELION 838 million miles (1.35 billion km) Sun

NORTHERN FALL EQUINOX

Saturn orbits the Sun in 29.46 Earth years

SPIN AND ORBIT

Saturn spins on its axis as it orbits. The rapid spin flings material outward, with the result that Saturn is about 10 percent wider at its equator than its poles. Its bulging equator is bigger than that of any other planet.

STRUCTURE Saturn’s mass is only 95 times that of Earth, yet 764 Earths could fit inside it. This is because Saturn is composed mainly of the lightest elements, hydrogen and helium, which are in both gaseous and liquid states. Saturn is the least dense of all the planets. If it were possible to put Saturn in an ocean of water, it would float. The planet has no discernible surface: its outer layer is gaseous atmosphere. Inside the planet, pressure and temperature increase with depth and the hydrogen and helium molecules are forced closer and closer together until they become fluid. Deeper still, the atoms are stripped of their electrons and act as a liquid metal. Electric currents within this region generate a magnetic field 71 percent the strength of Earth’s (see p.125). atmosphere outer layer of liquid hydrogen and helium

TH E S OL A R S Y ST E M

inner layer of liquid metallic hydrogen and helium core of rock and ice

SATURN’S INTERIOR

A thin, gaseous atmosphere surrounds a vast shell of liquid hydrogen and helium. The central core is about 10–20 times the mass of Earth.

RINGLEADER

Girdled by its bright system of rings, Saturn has a hazy, muted appearance in this Cassini image, which shows the planet in its natural colors.

189

ATMOSPHERE Saturn’s atmosphere forms the planet’s visible surface. It is seen as a pale-yellow cloud deck with muted bands of various shades, which lie parallel to the planet’s equator. Its upper clouds have a temperature of about –220°F (–140°C). The atmospheric temperature decreases with height, and as different compounds condense into liquid droplets at different temperatures, clouds of different composition form at different levels. Saturn is believed to have three cloud layers. The highest, visible layer is made of ammonia ice crystals; beneath this lies a layer of ammonium hydrosulfide; water-ice clouds, so far unseen, form the lowest layer. The upper atmosphere absorbs ultraviolet light, and the temperature rises here, leading to the production of a thin layer of smoggy haze; it is this layer that gives the planet its indistinct, muted appearance. The smog builds up on the hemisphere that is tilted toward the Sun. Saturn radiates almost twice the amount of energy it receives from the Sun. The extra heat is generated by helium rain droplets within the planet’s metallic shell. These convert motion energy to heat energy as they fall toward the planet’s COMPOSITION OF ATMOSPHERE center. The heat is transported The trace gases include methane, through the lower atmosphere ammonia, and ethane. It is not known and, along with the planet’s which elements or compounds color the rotation, generates Saturn’s winds. atmosphere’s clouds and spots. helium and trace gases 3.7%

hydrogen 96.3%

JANUARY 28, 2004

SATURN PROFILE

JANUARY 26, 2004 ROTATION PERIOD

888 million miles (1.43 billion km)

10.66 hours

CLOUDTOP TEMPERATURE

ORBITAL PERIOD (LENGTH OF YEAR)

–220°F (–140°C)

29.46 Earth years

DIAMETER

74,898 miles (120,536 km)

Solar-wind particles in the upper atmosphere produce aurorae. The brightening of the aurora on January 28 corresponds with the arrival at Saturn of a disturbance in the solar wind.

95

763.59

GRAVITY AT CLOUDTOPS (EARTH = 1)

NUMBER OF MOONS

62

SIZE COMPARISON

OBSERVATION

CHANGING SOUTH POLAR AURORA

MASS (EARTH = 1)

VOLUME (EARTH = 1)

Saturn is visible to the naked eye for about 10 months of the year. It appears like a star and takes about 2.5 years to pass though one zodiacal constellation. A telescope is needed to make out the ring system.

EARTH

1.07

SATURN

TH E S O LA R S Y S TE M

JANUARY 24, 2004

AVERAGE DISTANCE FROM THE SUN

190

SATURN

WEATHER Giant upper-atmosphere storms composed of white ammonia ice can be seen from Earth when they rise through the haze. They occur once every 30 years or so, when it is midsummer in the northern hemisphere, but, as yet, there is no accepted explanation for the storms. The last of these “Great White Spots” was discovered on September 25, 1990. It spread around the planet, almost encircling the equatorial region over about a month. Smaller, different-colored oval spots and ribbonlike features have been observed on a more regular basis. In 2004, Cassini revealed a region then dominated by storm activity, nicknamed “storm alley”. Wind speed and direction on the planet are determined by tracking storms and clouds. Saturn’s dominant winds blow eastward, in the same direction as the planet’s spin. Near the equator, they reach 1,200 mph (1,800 km/h).

BANDS AND SPOTS

Bands of clouds, spots, and ribbonlike features move across Saturn’s visible surface. The spots look small but can be thousands of miles across.

WHITE STORM ON SATURN

In December 2010, a white storm cloud appeared in Saturn’s northern hemisphere. This image shows the storm, which grew until it extended all the way around the planet, three weeks after it broke out.

C ring

B ring

MOONS

DIONE

Saturn has more than 60 known mooms. Most of these have been discovered since 1980, through exploration by the Voyager and Cassini probes and by improved Earth-based observing techniques. Future observations are expected to confirm the presence of more moons. Titan is the largest and was the first to be discovered, in 1655. It is a unique moon, being the only one in the solar system to have a substantial atmosphere. Saturn’s moons are mixes of rock and water ice. Some have ancient, cratered surfaces, and others show signs of resurfacing by tectonics or ice volcanoes. The moons are mostly named after mythological giants. The first to be discovered were named after the Titans, the brothers and sisters of Cronus (Saturn) in Greek mythology. More recent discoveries have Gallic, Inuit, and Norse names.

Cassini produced this image of the moon Dione against the backdrop of Saturn’s clouds in December 2005. This true-color view reveals the variations in brightness of the moon’s icy surface. Dione is Saturn’s fourthlargest moon.

SATURN’S MOONS

TH E S O LA R S Y S TE M

Hyperion 24.6

Iapetus 59.1

Titan 20.3

1 radius +

25

S/2009 S1 1.94

75

50

Aegaeon 2.78

Calypso 4.88

+

125

100

+

Tethys 4.88 Helene 6.26

175

150 Kiviuq 189

Dione 6.26 Daphnis 2.26

Telesto 4.88

Anthe 3.28

+ Pan 2.22

Atlas 2.28

Pandora 2.35

Polydeuces 6.26

Mimas 3.08

Rhea 8.75

Pallene 3.50

Janus 2.51 Prometheus 2.28

Epimetheus 2.51

Methone 3.22

Enceladus 3.95

Ijiraq 190

2

SATURN

191

RINGS Saturn’s visible rings are the most extensive, massive, and spectacular in the Solar System. From Earth, they appear as a band of material whose appearance changes according to Saturn’s position. The rings are, in fact, collections of separate pieces of dirty water ice following individual orbits round Saturn. The pieces range from dust grains to boulders several yards across. They are very reflective, so the rings are bright and easy to see. Individual rings are identified by letters, allocated in order of discovery. The readily seen rings are the C, B, and A rings. These are bounded by others, made of tiny particles, that are almost transparent. The thin F ring, the broader G ring, and the diffuse E ring lie outside the main rings. The D ring, inside C, completes the system. The rings change slowly over time, and moons orbiting within the system shepherd particles into rings and maintain gaps such as the MAIN RING SYSTEM Encke gap. Far beyond the visible This mosaic of six images shows the main system is a huge, doughnut-shaped rings in natural color and reveals the ring. Almost impossible to see, it was ringlets within the Cassini Division. The discovered in 2009 by the infrared distance from the inner edge of C to the F glow of its cool and sparse dust. ring is about 40,500 miles (65,000 km).

COMPOSITIONAL DIFFERENCES

In this ultraviolet image of the outer portion of the C ring (left) and inner B ring (right), red indicates the presence of dirty particles and turquoise indicates purer ice particles. Encke gap

Cassini Division

F ring

A ring

PROMETHEUS AND THE F RING

Saturn’s innermost moons orbit within the ring system and interact with it. Some act as shepherd moons, confining particles within specific rings. Prometheus (just below the rings in this image) and Pandora work in this way on either side of the F ring.

INVISIBLE RINGS

Saturn’s largest ring is invisible to the eye. It consists of dust and was discovered at infrared wavelengths by the Spitzer Space Telescope. Above is an artist’s representation of the ring, which lies between about 3.7 and 11.2 million miles (6 million and 18 million km) from Saturn. At the top is a Spitzer image of part of the ring. The ring is tilted about 27 degrees from Saturn’s main ring plane.

PANDORA

The small shepherd moon Pandora orbits just beyond the F ring. It is visible as a white dot in this view taken by Cassini on February 18, 2005.

Phoebe 215

S/2007 S2 278

Skathi 260

225

200

275

250

Siarnaq 301

325

300 Jarnsaxa 321 Suttungr 323 S/2004 S17 323

+

S/2004 S13 305

Greip 306

Narvi S/2006 S1 312 311 Mundilfari 310

S/2007 S3 315

Fenrir 373 Surtur 380

Erriapus 292 Skoll Tarqeq 297 293

Bergelmir 321

+

Kari 367 S/2006 S3 367

Tarvos 303

375

350 S/2004 S12 330

Hati 328

Scale in radii of Saturn

Farbauti 339

Bestia 337

1 1 radius = 37,448 miles (60,268 km)

Loge 383

Hyrrokkin 396 Fornjot 417

Ymir 383

400

Aegir 344

Thyrmr 340

S/2004 S7 349

Moons (and rings) are not to scale and increase in size for magnification purposes only

425

TH E S O LA R S Y S TE M

Albiorix 272 Bebhionn 284

Paaliaq 252

192

SATURN

SATURN’S MOONS The moons of Saturn are divided into three groups. The first consists of the major moons, which are large and spherical. The second group, the inner moons, are smaller and irregularly shaped. Members of both these groups orbit within or outside the ring system. The third set of moons lies far beyond the other two—the most distant orbit over 15 million miles (25 million km) from Saturn. These irregularly shaped moons are tiny, just a few miles to tens of miles across. They have inclined orbits, which suggests that DWARFED BY SATURN Saturn’s moons, such as Tethys (top) and they are captured objects. From Earth, Saturn’s moons appear as Dione (below), are not only small compared little more than disks of light, but Voyager and Cassini revealed to their host planet but, with the exception of many of them as worlds in their own right. Titan, they are all smaller than Earth’s Moon.

INNER MOON

INNER MOON

Prometheus DISTANCE FROM SATURN

86,539 miles

(139,353 km) ORBITAL PERIOD LENGTH

Epimetheus DISTANCE FROM SATURN

94,089 miles

(151,422 km) 0.61 Earth days

84 miles (136 km)

Prometheus is a small, elongated moon orbiting just inside the multi-stranded F ring. Along with Pandora, it is a “shepherd” of the F ring. Cassini images of Prometheus and the F ring show them to be linked by a fine thread of material, produced as Prometheus pulls particles out of the ring. The moon’s long axis points SHEPHERD MOON toward Saturn.

ORBITAL PERIOD LENGTH

0.69 Earth days

81 miles (130 km)

Occasionally, moons orbit a planet within about 30 miles (50 km) of each other. They are described as co-orbital since they virtually share an orbit. The two moons Epimetheus and Janus CO-ORBITAL MOON

Epimetheus orbits against the backdrop of Saturn’s rings, which are seen nearly edge-on in this view taken by Cassini’s narrow-angle camera on February 18, 2005.

(below left), which orbit just beyond the F ring, are such a pair. They swap orbits every four years, taking turns being slightly closer to Saturn. Epimetheus is a lumpy moon, just 17 miles (28 km) longer than it is wide or deep, and it is one of 16 moons that lie within the ring system. Epimetheus is in synchronous rotation—that is, it keeps the same face toward Saturn at all times because its rotation and orbital periods are the same. As it orbits Saturn, it works as a shepherd moon, confining the ring particles within the F ring. Prometheus (left) works the

INNER MOON

Janus DISTANCE FROM SATURN

94,120 miles

(151,472 km) ORBITAL PERIOD LENGTH

0.69 Earth days

126 miles (203 km)

Heavily cratered and irregularly shaped, Janus orbits Saturn just beyond the F ring and only 30 miles (50 km) farther away than its co-orbital moon, Epimetheus. Its existence was first reported in December 1966, and it was named after the Roman god Janus, who could look forward and back at the same time. Yet it was only confirmed as a moon in February 1980, after Voyager 1 data had been studied.

INNER MOON

TH E S O LA R S YS TEM

Pallene DISTANCE FROM SATURN

131,000 miles

(211,000 km) ORBITAL PERIOD DIAMETER

BEYOND THE F RING

1.14 Earth days

3 miles (5 km)

Two small moons orbiting between the major moons Mimas and Enceladus were discovered in 2004 in data collected by the Cassini probe. As with all such discoveries, the moons were initially identified by numerical designations (S/2004 S1 and S/2004 S2). The two moons are now known as Methone and Pallene. They were

not found by chance but were identified in images taken as part of a search for new moons within this region around Saturn. The contrast of the images was enhanced to increase visibility. Twenty-eight images, including the one on the right, acquired over a period of 9.25 hours together make a movie showing Pallene as it progresses along its orbital path around Saturn. S/2004 S2

Pallene is a tiny world, just 2.5 miles (4 km) long, which has only been seen as a bright dot. The large, bright object is Saturn, which has been overexposed in an attempt to record new, small, faint moons.

BATTERED SURFACE

Epimetheus (left) and its co-orbital moon, Janus, are believed to be the remnants of a larger object that was broken apart by an impact.

same way on the inner side of the ring. The existence of Epimetheus was suspected in 1967 but was not confirmed until February 26, 1980. It was one of eight moons discovered in Voyager data that year. The moon is named after a Titan, the family of giants in Greek mythology who once ruled the Earth. Prometheus was one of Epimetheus’s five brothers.

SATURN

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MAJOR MOON

Mimas DISTANCE FROM SATURN

115,208 miles

(185,520 km) ORBITAL PERIOD DIAMETER

0.94 Earth days

246 miles (396 km)

Mimas is the first of the major moons out from Saturn, and it orbits the planet in the outer part of the ring system. It is in synchronous rotation, so the same side of the moon always faces the planet, in the same way that one side of the Moon always faces Earth. Mimas is a round moon, but it is not a perfect sphere—this icy EMPHASIZING DIFFERENCES object is about 19 miles False color highlights slight (30 km) longer than it is differences in surface composition wide and deep. Its surface on Mimas, for example the bluish is covered in deep, bowlterrain near the crater Herschel, shaped impact craters. Many of those greater than possibly caused by impact ejecta, and greenish terrain elsewhere. about 12 miles (20 km) across have central peaks. One crater, Herschel, dwarfs the rest and is the moon’s most prominent feature. It is about 80 miles (130 km) wide, almost 6 miles (10 km) deep, and has a prominent central peak. If the impacting body that formed the crater had been much bigger, it might have smashed the moon apart. The crater is named after the astronomer William Herschel, who discovered Mimas on July 18, 1789. It was the sixth of Saturn’s moons to be discovered and the first of two discovered by Herschel. Mimas is named after a Titan (see p.190).

The crater Herschel lies on the moon’s leading hemisphere (the side that points in the direction in which it is moving) and is about one-third of the diameter of Mimas itself. The impact that formed Herschel must have come close to shattering the moon. TRUE BLUE

Mimas drifts against the backdrop of Saturn’s northern hemisphere in this true-color view. Scattering of sunlight in the relatively cloudfree area gives the planet a bluish hue. The dark lines cutting across the atmosphere are shadows cast by Saturn’s rings.

TH E S OL A R S Y S TE M

GIANT CRATER

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SATURN MAJOR MOON

Enceladus DISTANCE FROM SATURN

BLUE WALLS 147,898 miles

(238,020 km) ORBITAL PERIOD DIAMETER

1.37 Earth days

313 miles (504 km)

WATER JETS

Enceladus orbits within the broad E ring of Saturn. Its orbit lies within the densest part of the ring, which suggests that Enceladus could be supplying the ring with material. The moon is in synchronous rotation with Saturn. The frosty surface of Enceladus is highly reflective and makes this moon particularly bright, the brightest in the solar system. The surface terrain suggests that this frigid moon has experienced a long history of tectonic activity and resurfacing. The extent of the geological change is surprising in such a small world—

A false-color view reveals long fractures (in blue) on the moon’s icy surface. The walls of the fractures are thought to expose ice with coarser texture than on the smooth surface.

Ice and water vapor spray out from so-called tiger stripes near the south pole of Enceladus, as shown here in this image from the Cassini probe.

Mimas (see p.193) is about the same size but is inactive. Craters are concentrated in some regions, and elsewhere there are grooves, fractures, and ridges. Images processed to accentuate color differences have revealed previously unseen detail. The blue color seen in some fracture walls could be due to the exposure of solid ice, or because the composition or size of particles in the buried ice is different from that on the surface. Enceladus was discovered by William Herschel on August 28, 1789.

SMOOTH PLAINS

This region of smooth plains has a band of chevronshaped features running across its center, cut across at the top by a system of crevasses.

INNER MOON

183,093 miles

(294,660 km) ORBITAL PERIOD LENGTH

This is a closeup of part of Baghdad Sulcus, the longest of several linear structures popularly termed tiger stripes in the south polar region of Enceladus.

ICY MOON

Telesto DISTANCE FROM SATURN

BAGHDAD SULCUS

1.89 Earth days

The pale, icy disk of Tethys was imaged by Cassini on January 18, 2005 as it orbited below Saturn’s south polar region, where fierce storms were raging.

MAJOR MOON

Tethys DISTANCE FROM SATURN

ORBITAL PERIOD

20 miles (32.5 km)

DIAMETER

Telesto shares an orbit within the E ring with two other moons: Calypso, which is about the same size as Telesto; and the much larger Tethys (right). Telesto moves along the orbit 60° ahead of Tethys, and Calypso follows 60° behind Tethys. The positions taken on the orbit by the two smaller moons are called the Lagrange points. In these positions, the two small moons can maintain a stable orbit balanced between the gravitational pull of Saturn and that of Tethys. Telesto and Calypso were discovered in 1980; Calypso by Earthbased observation and Telesto in Voyager images. The probe revealed two irregularly shaped moons. SMOOTH MOON

Telesto’s surface appears less cratered than most of Saturn’s other moons in this image taken by Cassini from a distance of only 9,000 miles (14,500 km).

183,093 miles

(294,660 km) 1.89 Earth days

660 miles (1,062 km)

The Italian–French astronomer Giovanni Cassini discovered Tethys on March 21, 1684. Nearly 200 years later, it was discovered that Tethys shares its orbit with two far smaller moons: Telesto (left) and Calypso. Its surface shows that Tethys has undergone tectonic change and resurfacing. Two features stand out. A 248-mile(400-km-) wide impact crater called Odysseus dominates the leading hemisphere. Large but shallow, its original bowl shape has been flattened by ice flows. The second large feature is the Ithaca Chasma on the side of Tethys facing Saturn. This vast canyon system extends across half of the moon. It may have been formed by tensional fracturing as a result of the impact that produced the Odysseus Crater, or when Tethys’s interior froze and the moon expanded in size and stretched its surface. ITHACA CHASMA

This canyon system, which is up to 2.5 miles (4 km) deep, runs from the lower left of the prominent Telemachus Crater (top right).

195 MAJOR MOON

Dione DISTANCE FROM SATURN

234,505 miles

(377,400 km) ORBITAL PERIOD DIAMETER

2.74 Earth days

698 miles (1,123 km)

Dione is the most distant moon within Saturn’s ring system, but it is not alone in the outer reaches of the E ring. Two other moons, Helene and Polydeuces, follow the same orbit, Helene is ahead of Dione by 60° and Polydeuces follows 60° behind. Helene was discovered in March 1980; Polydeuces was discovered in Cassini data some 24 years later, just after the probe arrived at Saturn. Giovanni Cassini discovered Dione in 1684, on the same day that he discovered Tethys (opposite). Dione has a higher proportion of rock in its rock–ice mix than most of the other moons (only Titan has more), and so

IMPACT CRATERS

The well-defined central peaks of Dione’s largest craters are visible in this Voyager image. Dido Crater lies just left of center, with Romulus and Remus just above it and Aeneas Crater near the upper limb.

it is the second-densest of Saturn’s moons. The terrain displays evidence of tectonic activity and resurfacing. There are ridges, faults, valleys, and depressions. There are also craters, which are more densely distributed in some regions than others—Dione’s leading face, for example, has more than the trailing face. The largest crater is over 124 miles (200 km) across. Dione also has bright streaks on its surface. These wispy features are composed of narrow, bright, icy lines. DIONE’S FAR SIDE

Impact craters scar the surface of the side of Dione that is permanently turned away from Saturn because it is in synchronous rotation. Areas of wispy terrain are visible on the left of this image.

ANCIENT SURFACE

MAJOR MOON

Rhea DISTANCE FROM SATURN ORBITAL PERIOD DIAMETER

327,487 miles (527,040 km)

4.52 Earth days

Two large impact basins (top center) are visible in this enhanced-color image of Rhea’s heavily cratered surface. The great age of these basins is indicated by the many smaller craters upon them.

949 miles (1,527 km)

Vast sweeps of ancient cratered terrain cover large parts of Rhea. At first glance, the landscape resembles that seen on Earth’s Moon, although Rhea’s surface is bright ice. There is some evidence of resurfacing, although not as much as expected for such a large moon. Rhea is Saturn’s second-largest moon, but other, smaller moons, such as its inner neighbors Dione and Tethys, show more resurfacing. It is thought that

Rhea froze early in its history and became frigid. Its ice would then have behaved like hard rock. Rhea’s craters, for example, are freshly preserved in its icy crust. The craters on other icy moons, such as Jupiter’s Callisto (see p.187), have collapsed in the soft, icy crust. Rhea is the first of Saturn’s moons to lie beyond the ring system. It is named after the Titan Rhea, who was the mother of Zeus in Greek mythology. HEAVILY CRATERED

Rhea’s icy surface is heavily cratered, suggesting that it dates back to the period immediately following the formation of the planets. This image shows the region around the moon’s North Pole. The largest craters are several miles deep.

CLIFFS OF ICE

A Cassini close-up of Dione’s wispy terrain reveals that it is formed from lines of ice cliffs created by tectonic fractures, rather than deposits of ice and frost as was previously thought.

An enhanced-color view of the surface of Rhea shows blue patches of freshly uncovered ice. The ice is thought to have been exposed when debris in orbit around Rhea struck the surface along the equator.

TH E S OL A R S Y S TE M

FRESH ICE

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SATURN MAJOR MOON

Titan DISTANCE FROM SATURN

758,073 miles

(1.22 million km) ORBITAL PERIOD DIAMETER

15.95 Earth days

3,200 miles (5,150 km)

Titan was discovered in 1655 by the Dutch scientist Christiaan Huygens. It is the second-largest moon in the solar system after Jupiter’s Ganymede (see p.186) and is by far the largest of Saturn’s moons. This Mercury-sized body is also one of the most fascinating. A veil of smoggy haze shrouds the moon and permanently obscures the world below. Titan is intriguing, not least because the TITAN’S ATMOSPHERE

Infrared and ultraviolet data combined reveals aspects of the atmosphere. Areas where methane absorbs light appear orange and green. The high atmosphere is blue.

chemistry of the atmosphere has similarities to that of the young Earth, before life began. The first chance to see the surface and test the atmosphere came in 2005, when Cassini turned its attention to Titan, and Huygens plunged through the atmosphere to the surface (see panel, right). The nitrogen-rich atmosphere extends for hundreds of miles above Titan. Layers of yellow-orange, smoglike haze high within it are the result of chemical reactions triggered by ultraviolet light. Methane clouds form much closer to the surface. These rain methane onto Titan, where it forms rivers and lakes. It then evaporates and forms clouds, and the cycle, which is reminiscent of the water cycle on Earth, continues. Titan is the densest of Saturn’s moons: it is a 50:50 mix of rock and water ice with a surface temperature of –292°F (–464°C). It is a gloomy world because the smog blocks 90 percent of the incident sunlight. Cassini revealed

EXPLORING SPACE

THE HUYGENS PROBE The European probe Huygens traveled to Titan onboard NASA’s Cassini spacecraft. Once there, it separated from the larger craft and parachuted into Titan’s haze. During its 2.5-hour descent, Huygens tested the atmosphere, measured the speed of the buffeting winds, and took images of the moon’s surface. An instrument recorded the first surface touch on January 14, 2005, sending back evidence of a thin, hard crust with softer material beneath. HUYGENS AND CASSINI

The shield-shaped Huygens probe (right) is attached to Cassini’s frame in preparation for the launch from Cape Canaveral, Florida, in October 1997.

that its surface is shaped by Earth-like processes— tectonics, erosion, and winds—and perhaps ice volcanism. No liquid methane was detected on the initial flybys, but drainage channels and dark elliptical regions, thought to be evaporated lakes, showed where fluids had been. Linear features nicknamed “cat scratches” were also identified.

POLAR LAKES

Lakes of liquid methane and ethane have formed at Titan’s north pole. The lakes are shown in blue. The largest are bigger than the Great Lakes of North America, but much shallower.

ORANGE AND PURPLE HAZE

T HE SO LA R S Y S TE M

The upper atmosphere consists of separate layers of haze; up to 12 have been detected in this ultraviolet, true-color image of Titan’s night-side limb.

ICY SURFACE

TITAN REVEALED

The surface of Titan is shown in this image taken by the Huygens lander in 2005. The pebbles in the foreground are up to about 6 in (15 cm) across and are thought to be composed of frozen water.

Infrared observations that cut through Titan’s clouds reveal bright highlands, dark lowlands, and a possible impact basin near the disk’s center.

SATURN INNER MOON

Hyperion DISTANCE FROM SATURN

919,620 miles

(1.48 million km) 21.28 Earth days

ORBITAL PERIOD LENGTH

224 miles (360 km)

Nothing about Hyperion is typical. First, it is an irregularly shaped moon with an average width of about 174 miles (280 km). This makes it one of the largest nonspherical bodies in the solar system. Second, it follows an elliptical orbit just beyond Saturn’s largest moon, Titan (opposite). And, as it orbits, it rotates chaotically: its rotation axis wobbles, and the moon appears to tumble as it travels. Its

197

surface is cratered, and there are segments of cliff faces. Its shape and scarred surface suggest Hyperion could be a fragment of a once-larger object that was broken by a major impact. Even Hyperion’s discovery was unusual. Astronomers in the US and England found it independently and within two days of each other in September 1848.

STRANGE CRATERS

Hyperion has a strange, spongy appearance, resulting from its low density and weak gravity. CRATER FLOOR

OUTER MOON

Phoebe DARK COATING

Iapetus, the two-toned moon of Saturn, is seen in this closeup from the space probe Cassini. One side of Iapetus consists of bright ice, while the other is covered with a dark coating.

MAJOR MOON

Iapetus DISTANCE FROM SATURN

2.21 million miles

DISTANCE FROM SATURN

8.05 million miles

(12.95 million km) ORBITAL PERIOD DIAMETER

550 Earth days

132 miles (213 km)

Phoebe was discovered in 1898 and, until 2000, was thought to be Saturn’s only outer moon. Many others are now known to exist. Phoebe has a long orbital period and follows a highly inclined orbit, a characteristic of the outer moons. Phoebe’s orbit is inclined by 175.3° and so it travels in a retrograde manner (backward

Debris covers the floor of this impact crater. The streaks inside the crater indicate where loose ejecta has slid down toward the center.

compared to most moons). Half the outer moons orbit this way. Phoebe is by far the largest outer moon; the others are, at most, only 12 miles (20 km) across. From Cassini images, it appears to be an ice-rich body coated with a thin layer of dark material.

(3.56 million km) ORBITAL PERIOD DIAMETER

Erginus

79.33 Earth days

BLASTED PHOEBE

913 miles (1,469 km)

SURFACE COMPOSITION

False colors represent Iapetus’s vastly different surface compositions. Bright blue signifies an area rich in water ice, dark brown indicates a substance rich in organic material, and the yellow region is composed of a mix of ice and organic chemicals.

LANDSLIDE IN CASSINI REGIO

Land has collapsed down a 9-mile- (15-km-) high scarp, which marks the edge of a huge impact crater, into a smaller crater. The long distance traveled by the material along the floor indicates that it could be fine-grained.

Jason

on the bright side. Although the Cassini probe revealed more of the moon’s heavily cratered surface, the origin of the dark material remains a mystery. It has been suggested that the material erupted from the moon’s interior, or that it is ejecta from impacts on a more distant moon, such as Phoebe (right). A unique feature revealed by Cassini has provided another mystery. It is not known whether a 800-mile- (1,300-km-) long ridge that coincides almost exactly with the moon’s equator is a folded mountain belt or material that erupted through a crack in the surface.

Iphitus

Euphemus

Butes

Eurydamas

Canthus

Oileus

TH E S OL A R S Y S TE M

Most of Saturn’s inner and major moons orbit in the equatorial plane (also the plane of the rings). Iapetus is an exception, its orbit being inclined by 14.72° to the equatorial plane. Other moons follow orbits with greater inclination, but these are the much smaller, outer moons. Iapetus is Saturn’s most distant major moon. It is also in synchronous rotation. Iapetus was discovered by Italian astronomer Giovanni Cassini while he was working from Paris on October 25, 1671. He noticed that Iapetus has a naturally dark leading hemisphere and a bright trailing hemisphere. The dark region is called Cassini Regio and is covered in material as dark as coal, in contrast to the icy surface

Phoebe’s impact craters were revealed by Cassini in June 2004. They are named after the Argonauts in Greek mythology. The largest, Jason, is about 60 miles (100 km) across.

SATURN FROM ABOVE

This is Saturn as it can never be seen from Earth—looking down from above, with the full sweep of the rings encircling the planet. In a complex interplay of light and shade, the shadow of the rings inscribes a dark line around the planet, while the inky black of the planet’s shadow falls across the rings. This image, looking toward the unlit side of the rings, was taken by the Cassini probe.

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URANUS

URANUS

PALE BLUE DISK

Voyager 2 images have been combined to show the southern hemisphere of Uranus as it would appear to a human on board the spacecraft.

URANUS IS THE THIRD-LARGEST

planet and lies twice as far from the Sun as its neighbor 68–69 Planetary motion Saturn. It is pale blue and featureless, with a 100–101 The history of the solar system sparse ring system and an extensive family of moons. 102–103 The family of the Sun The planet is tipped on its side, and so from Earth the moons and rings appear to encircle it from top to bottom. Uranus was the first planet to be discovered by telescope, but little was known about it until the Voyager 2 spacecraft flew past in January 1986. 38–39 Gravity, motion, and orbits

ORBIT

Uranus takes 84 Earth years to complete one orbit around the Sun. Its axis of rotation is tipped over by 98°, and the planet moves along the orbital path on its side. Uranus’s spin is retrograde, spinning in the opposite direction of most planets. The planet would not have always been like this. Its sideways stance is probably the result of a collision with a planet-sized body when Uranus was young. Each of the poles points to the Sun for 21 years at a time, during the periods centered on the solstices. This means that while one pole experiences a long period of continuous sunlight, the other experiences a similar period of complete darkness. The strength of the sunlight received by the planet is 0.25 percent of that on Earth. When Voyager encountered Uranus in 1986, its south pole was pointing almost directly at the Sun. Uranus’s equator then became increasingly edge-on to the Sun. After 2007, it has progressively turned away, and the north pole will face the Sun in 2030.

EQUINOX (2007)

orbits the Sun in 84 Earth years

APHELION 1.86 billion miles (3.0 billion km)

NORTHERN WINTER SOLSTICE (1985) South Pole points toward Sun

PERIHELION 1.7 billion miles (2.74 billion km)

EQUINOX (1965)

Sun

equator faces Sun

spins on its axis once every 17.24 hours

STRUCTURE

TH E S O LA R S Y S TE M

axis tilts from vertical by 98°

NORTHERN SUMMER SOLSTICE (2030)

South Pole points away from Sun

Uranus is big. It is four times the size of Earth and could contain 63 Earths inside it; yet it has only 14.5 times the mass of Earth. So the material it is made of must be less dense than that of Earth. Uranus is too massive for its main ingredient to be hydrogen, which is the main constituent of the bigger planets, Saturn and Jupiter. It is made mainly of water, methane, and atmosphere of ammonia ices, which are hydrogen, helium, surrounded by a gaseous and other gases layer. Electric currents layer of water, within its icy layer are methane, and believed to generate the ammonia ices planet’s magnetic field, which is offset by 58.6° from Uranus’s spin axis. core of rock and possibly ice

SPIN AND ORBIT

Uranus’s long orbit and its extreme tilt combine to produce long seasonal differences. Each pole experiences summer when pointing toward the Sun and winter when it is pointing away. At such times, the pole is in the middle of Uranus’s disk when viewed from Earth. At the equinoxes, the equator and rings are edge-on to the Sun.

URANUS PROFILE

AVERAGE DISTANCE FROM THE SUN

ROTATION PERIOD

1.78 billion miles (2.87 billion km)

17.24 hours

CLOUDTOP TEMPERATURE

ORBITAL PERIOD (LENGTH OF YEAR)

–364°F (–220°C)

84 Earth years

DIAMETER

31,763 miles (51,118 km)

URANUS INTERIOR

14.5

63.1

GRAVITY AT CLOUDTOPS (EARTH = 1)

NUMBER OF MOONS

27

SIZE COMPARISON

OBSERVATION

Uranus does not have a solid surface. The visible surface is its atmosphere. Below this lies a layer of water and ices, which surrounds a small core of rock and possibly ice.

MASS (EARTH = 1)

VOLUME (EARTH = 1)

Uranus’s remote location makes it a difficult object to view from Earth. At magnitude 5.5, it is just visible to the naked eye and looks like a star. There is no perceptible change in brightness when Uranus is at opposition.

EARTH

URANUS

0.89

URANUS

ATMOSPHERE AND WEATHER

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CLOUDS

This Keck II telescope

Uranus’s blue color is a result of the absorption of the incoming infrared image has been processed to show vertical sunlight’s red wavelengths by methane-ice clouds within the structure. The highest planet’s cold atmosphere. The cloud-top temperature of clouds appear white; mid-364°F (-220°C) appears to be fairly uniform across level ones, bright blue; and the planet. The action of ultraviolet sunlight on the the lowest clouds, darker methane produces haze particles, and these hide the blue. As a byproduct, the rings are colored red. lower atmosphere, making Uranus appear calm. The planet is, however, actively changing. The Voyager 2 data revealed the movement of ammonia and water clouds around Uranus, carried by wind and the planet’s rotation. It also revealed that Uranus radiates about the same amount of energy as it receives from the Sun and has no significant internal heat to drive a complex weather system. More recently, observations made using ground-based telescopes have also made it possible for astronomers to track changes COMPOSITION OF ATMOSPHERE in Uranus’s atmosphere. The atmosphere is made mainly of hydrogen, which extends beyond the visible cloudtops and forms a corona around Uranus.

methane 2.3%

helium 15.2%

hydrogen 82.5%

RINGS AND MOONS

EXPLORING SPACE

RINGS DISCOVERED

Uranus has 11 rings that together extend out from 7,700 to 15,900 miles (12,400–25,600 km) from the planet. The rings are so widely separated and so narrow that the system has more gap than ring. All but the inner and outer rings are between 0.6 and 8 miles (1 km and 13 km) wide, and all are less than 9 miles (15 km) high. They are made of charcoal-dark pieces of carbon-rich material measuring from a few inches to possibly a few yards across, plus dust particles. The first five rings were discovered in 1977 (see panel, right). The rings do not lie quite in the equatorial plane, nor are they circular or of uniform width. This is probably due to the gravitational influence of small, nearby moons. One of these, Cordelia, lies within the ring system. Uranus has 27 moons. The five major moons were discovered using Earth-based telescopes. Smaller ones have been found since the mid-1980s, through analysis of Voyager 2 data or by using today’s improved observing techniques. More discoveries are expected.

In March 1977, astronomers onboard the Kuiper Airborne Observatory, an adapted highflying aircraft, were preparing to observe a rare occultation of a star by Uranus, in order to measure the planet’s diameter. Before the star was covered by the planet’s disk, it blinked on and off five times. A second set of blinks was recorded after the star appeared from behind the planet. Rings around Uranus had blocked out the star’s light. KUIPER AIRBORNE OBSERVATORY

Astronomers and technicians operate an infrared telescope, which looks out to space through an open door in the side of the aircraft.

FALSE-COLOR VIEW OF THE RINGS

Nine of Uranus’s rings are visible in this Voyager 2 image. The faint pastel lines are due to image enhancement. The brightest, colorless ring (far right) is the outermost ring, epsilon. To its left are five rings in shades of blue-green, then three in off-white. URANUS’S MOONS Francisco 167.3

Caliban 282.9 Trinculo 335.3

1 radius +

100

Cordelia 1.95

Ferdinand 821.6

Stephano 313.1

Oberon 22.8

200

Puck 3.37

300

Margaret 561.3

400

500

600

700

800

Miranda 5.08 Umbriel 10.41

Ariel 7.48

Desdemona 2.45 Bianca 2.32 Cressida 2.42

Setebos 683.1

Mab 3.82

Ophelia 2.10

+

Prospero 642.4

Sycorax 476.5

Juliet 2.52

Portia 2.59

Belinda 2.94 Rosalind 2.74

Perdita 2.99

Cupid 2.93

1

Scale in radii of Uranus 1 radius = 15,872 miles (25,559 km)

Moons (not to scale) increase in size for magnification purposes

TH E S OL A R S Y S TE M

Titania 17.1

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URANUS’S MOONS Uranus’s moons can be divided into three groups. Moving out from Uranus, they are: the small inner satellites; the five major moons, which orbit in a regular manner; and the small outer moons, many of which follow retrograde orbits. Much of what is known about the moons, and the only close-up views, came from the Voyager 2 flyby in 1985-86. This revealed the major moons to be dark, dense rocky bodies with icy surfaces, featuring impact craters, fractures, and volcanic water-ice flows. The moons THE VIEW FROM EARTH Some of the 27 moons that orbit Uranus are named after characters in the plays of the can be seen in this infrared image, which English dramatist William Shakespeare or in the was taken by the Hubble Space verse of the English poet Alexander Pope. Telescope in 1998. INNER MOON

Cordelia DISTANCE FROM URANUS ORBITAL PERIOD DIAMETER

30,910 miles (49,770 km)

0.34 Earth days

25 miles (40 km)

Cordelia is the innermost and one of the smallest of Uranus’s moons. A team of Voyager 2 astronomers discovered it on January 20, 1986. Cordelia was one of 10 moons that were discovered in the weeks between December 30, 1985 and January 23, 1986 as the Voyager 2 spacecraft flew by Uranus and transmitted images

back to Earth. Astronomers had expected to find some more moons in orbit around Uranus. In particular, it was expected that pairs of shepherd moons—moons that are positioned on either side of a ring and keep the ring’s constituent particles in place— would be found. Surprisingly, just one pair, that of Cordelia and Ophelia, was discovered. Cordelia takes its name from the daughter of Lear in Shakespeare’s King Lear.

INNER MOON

INNER MOON

Ophelia DISTANCE FROM URANUS ORBITAL PERIOD DIAMETER

Puck 33,400 miles (53,790 km)

0.38 Earth days

26 miles (42 km)

Ophelia is one of a pair of moons that orbit either side of Uranus’s outer ring, the epsilon ring. It was discovered at the same time as its partner, Cordelia, on January 20, 1986. The two are small, not much bigger than the particles that make up the thin, narrow ring. The moon is named after the heroine in Shakespeare’s Hamlet.

SHEPHERD MOON

Cordelia is the innermost of two shepherd moons lying on either side of Uranus’s bright outer ring.

Miranda ORBITAL PERIOD

TH E S O LA R S YS TEM

DIAMETER

ORBITAL PERIOD DIAMETER

53,410 miles (86,010 km)

0.76 Earth days

101 miles (162 km)

Puck was discovered on December 30, 1985 and was the first of the 10 small moons to be found in the Voyager 2 data. It is the secondfarthest inner CRATERED MOON moon from Uranus and was discovered as the probe approached the planet. There was time to calculate that an image could be recorded on January 24, the day of closest approach. The image (above) revealed an almost circular moon with craters. The largest crater (upper right) is named Lob, after a British Puck-like sprite.

FULL DISK

MAJOR MOON

DISTANCE FROM URANUS

OPHELIA LIES OUTSIDE THE EPSILON RING

DISTANCE FROM URANUS

80,350 miles (129,390 km)

1.41 Earth days

300 miles (480 km)

Miranda is the smallest and innermost of Uranus’s five major moons, and was discovered by Dutch-born American astronomer Gerard Kuiper on February 16, 1948. When all five major moons were seen in close-up for the first time, on January 24, 1986, it was Miranda that gave astronomers the biggest surprise. As Voyager 2 passed within 19,870 miles (32,000 km) of its surface, the probe revealed a bizarrelooking world, where various surface features butt up against one another in a seemingly GEOLOGICAL MIX

On the left lies an ancient terrain of rolling hills and degraded craters; to the right is a younger terrain of valleys and ridges.

The complex terrain of the bright, chevronshaped Inverness Corona stands out in this south polar view of Miranda.

unnatural way. One explanation for this strange appearance is that Miranda experienced a catastrophic collision in its past. The moon shattered into pieces and then reassembled in the disjointed way seen today. An alternative theory says that the moon’s evolution was halted before it could be completed. Soon after its formation, dense, rocky material began to sink and lighter material, such as water ice, rose to the surface. This process then stopped because the necessary internal heat had disappeared. The surface clearly has different types of terrain from different time periods.

CRATERS AND FAULTS

Many different-sized impact craters can be seen in this 125-mile- (200-km-) wide region of rugged, high-elevation terrain, indicating that it is older than the lower terrain. Faults cut across the terrain at lower right.

URANUS FULL DISK

MAJOR MOON

Titania DISTANCE FROM URANUS ORBITAL PERIOD DIAMETER

203

270,700 miles (435,910 km)

8.7 Earth days

979 miles (1,578 km)

At a little less than half the size of the Moon, Titania is Uranus’s largest moon. This rocky world has a gray, icy surface that is covered by impact craters. Icy material ejected when the craters formed reflects the light and stands out on Titania’s surface. Large cracks are also visible and are an indication of an active interior. Some of these cut across the craters and appear to be the moon’s most recent geological features. They were

At top right is Titania’s largest crater, Gertrude, which is 202 miles (326 km) across. Below it, the Messina Chasmata cuts across the moon.

probably caused by the expansion of water freezing under the crust. There are also smooth regions with few craters that may have been formed by the extrusion of ice and rock. Titania was discovered by the German-born astronomer William Herschel on January 11, 1787, using his homemade 20-ft (6-m) telescope in his backyard in England.

MYTHS AND STORIES

QUEEN OF THE FAIRIES

VOYAGER 2 MOSAIC

MAJOR MOON

Ariel DISTANCE FROM URANUS ORBITAL PERIOD DIAMETER

118,620 miles (191,020 km)

2.52 Earth days

722 miles (1,162 km)

Ariel and Umbriel (below) were both discovered on October 24, 1851 by the English brewer and astronomer William Lassell (see p.207). Ariel is named after a spirit in Shakespeare’s play The Tempest. Of the four largest moons, this is the brightest, with the youngest surface. It has impact craters, but COMPLEX TERRAIN

The long, broad valley faults in Ariel’s southern hemisphere are filled with deposits and are more sparsely cratered than the surrounding terrain.

MAJOR MOON

Umbriel DISTANCE FROM URANUS

DIAMETER

140,530 miles (226,300 km)

4.14 Earth days

726 miles (1,169 km)

Umbriel is the darkest of Uranus’s major moons, reflecting only 16 percent of the light striking its surface. It is just slightly larger than Ariel, a fact confirmed by the Voyager 2 data. Previous observations had led astronomers to believe that Umbriel was much smaller. This was because of the difficulty in observing

Four Voyager 2 images were combined to produce this view of Ariel. Kachina Chasmata slices across the top, and the Domovoy Crater is on the left, below the centre. Below and to its right is the 30-mile- (50-km-) wide Melusine Crater, which is surrounded by bright ejecta.

these are relatively small—many are just 3–6 miles (5–10 km) wide. Domovoy, at 44 miles (71 km) across, is one of the largest. The sites of any older, larger craters that Ariel once had have been resurfaced. Long faults that formed when Ariel’s crust expanded cut across the moon to a depth of 6 miles (10 km). One fault, Kachina Chasmata, is 386 miles (622 km) long. The floors of such valleys are covered in icy deposits that seeped to the surface from below. such a small, distant moon that reflects little light. Voyager 2 revealed a world covered in craters, many of which are tens of miles across. Unlike Ariel, Umbriel appears to have no bright, young ray craters, which means that its surface is older. There is no indication that it has been changed by internal activity. Umbriel’s one bright feature, Wunda, is classified as a crater although its nature is unknown.

MAJOR MOON

OUTER MOON

Oberon

Caliban

DISTANCE FROM URANUS ORBITAL PERIOD DIAMETER

362,370 miles (583,520 km)

13.46 Earth days

946 miles (1,523 km)

Oberon was the first Uranian moon to be discovered—William Herschel observed it before spotting Titania. It has an icy surface pockmarked by ancient impact craters. There are several large craters surrounded by bright ejecta rays. Hamlet, which is just below center in the Voyager 2 image below, has a diameter of 184 miles (296 km). Its floor is partially covered by dark material, and it has a bright central peak. A 4-mile- (6-km) high mountain protrudes from the lower left limb of the moon.

DISTANCE FROM URANUS

4.5 million miles

(7.2 million km) ORBITAL PERIOD DIAMETER

579.5 Earth days

60 miles (96 km)

Caliban and another small moon, Sycorax, were discovered in September 1997. Both moons follow retrograde and highly inclined orbits. Sycorax is the more distant of the two, at 7.6 million miles (12.2 million km) from Uranus. They were the first of Uranus’s irregular moons to be discovered and are believed to be icy asteroids that were captured soon after the planet’s formation.

SOUTHERN HEMISPHERE

Umbriel is almost uniformly covered by impact craters. Its one bright feature, the 81-mile- (131-km-) wide Wunda at the top of this image, is, unfortunately, virtually hidden from view.

CALIBAN DISCOVERED

ICY SURFACE

Caliban lies within the square outline in this image, which was taken using the Hale telescope at Mount Palomar, California. The glow on the right is from Uranus, and the bright dots are background stars.

TH E S OL A R S Y S TE M

ORBITAL PERIOD

Titania and Oberon are the king and queen of the fairies in William Shakespeare’s play A Midsummer Night’s Dream. After a disagreement, Oberon squeezes flower juice into Titania’s eyes as she sleeps so that on awakening she will fall in love with the next person she sees. Titania wakes and falls in love with Bottom, the weaver (seen here in a movie still from 1999), who has been given an ass’s head by the impish sprite Puck.

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NEPTUNE

NEPTUNE NEPTUNE IS THE SMALLEST

and the coldest of the four gas giants, as well as the most distant from 68–69 Planetary motion the Sun. It was discovered in 1846, and just 100–101 The history of the solar system one spacecraft, Voyager 2, has been to 102–103 The family of the Sun investigate this remote world. When the probe flew by in 1989, it provided the first close-up view of Neptune and revealed that it is the windiest planet in the solar system. Voyager 2 also found a set of rings encircling Neptune, as well as six new moons. 38–39 Gravity, motion, and orbits

ORBIT Neptune takes 164.8 Earth years to orbit the Sun, which means that it has completed only one circuit since its discovery in 1846. The planet is tilted to its orbital plane by 28.3°, and as it progresses on its orbit, the north and south poles point sunward in turn. Neptune is about 30 times farther from the Sun than Earth, and at this distance the Sun is 900 times dimmer. Yet this remote, cold world is still affected by the Sun’s heat and light and apparently undergoes seasonal change. Ground-based and Hubble Space Telescope observations show that the southern hemisphere has grown brighter since 1980, and this, as well as an observed increase in the amount, width, and brightness of banded cloud features, has been taken as an indication of seasonal change. However, a longer period of observations is needed to be sure that this seasonal model is correct. The change is slow and the seasons are long. The southern hemisphere is currently in the middle of summer. Once SPIN AND ORBIT Neptune’s orbit is elliptical, but this is over, it is expected to move through less so than most planets. Only fall, into a colder winter. Then, after Venus has a more circular orbit. 40 years of spring and a gradual increase This means there is no marked in temperature and brightness, it will difference between Neptune’s aphelion and perihelion distances. experience summer once more. NORTHERN FALL EQUINOX

NORTHERN SUMMER SOLSTICE

spins on its axis every 16.11 hours

Sun

APHELION 2.82 billion miles (4.54 billion km)

PERIHELION 2.76 billion miles (4.44 billion km) axis tilts from the vertical by 28.3°

NORTHERN WINTER SOLSTICE

orbits the Sun every 164.8 years

NORTHERN SPRING EQUINOX

TH E S O LA R S YS TEM

STRUCTURE Neptune is very similar in size and structure to Uranus, and neither planet has a discernible solid surface. Like its inner neighbor, Neptune is too massive in relation to its size to be composed mainly of hydrogen. Only about 15 percent of the planet’s mass is hydrogen. Its main ingredient is a mix of water, ammonia, and methane ices that makes up the planet’s biggest layer. Neptune’s magnetic field, which is tilted by 46.8° to the spin axis, originates in this layer. Above it lies the atmosphere. This is a shallow, hydrogen-rich layer that also contains helium and methane gas. Below the layer of water and ices, there is a small core of rock and possibly ice. The boundaries between the layers are not clearly defined. The planet rotates quickly on its axis, taking 16.11 hours for one spin, and as a result Neptune has an equatorial bulge. Its polar diameter is 527 miles (848 km) less than its equatorial diameter.

atmosphere of hydrogen, helium, and methane gases layer of water, methane, and ammonia ices

core of rock and possibly ice

NEPTUNE’S INTERIOR

Neptune’s atmosphere is the planet’s visible surface. Below it lies a layer of water and ices, which surrounds a core of rock and possibly ice.

NEPTUNE THE BLUE PLANET

205

NEPTUNE PROFILE

This image of Neptune, which was taken by Voyager 2 on August 19, 1989, reveals the planet’s dynamic atmosphere. The Great Dark Spot, which is almost as big as Earth, lies in the center of the planet’s disk. A little dark spot and, just above it, the fastmoving cloud feature named the Scooter, are visible on the west limb. A band of cloud stretches across the northern polar region.

AVERAGE DISTANCE FROM THE SUN

ROTATION PERIOD

2.8 billion miles (4.5 billion km)

16.11 hours

CLOUDTOP TEMPERATURE

ORBITAL PERIOD (LENGTH OF YEAR)

–360ºF (–218ºC)

164.8 years

DIAMETER

30,760 miles (49,532 km)

MASS (EARTH = 1)

17.1

VOLUME (EARTH = 1)

57.74

GRAVITY AT CLOUDTOPS (EARTH = 1)

NUMBER OF MOONS

13

SIZE COMPARISON EARTH

OBSERVATION

1.13

NEPTUNE

Even at its maximum magnitude of 7.8, Neptune is beyond naked-eye visibility. Binoculars or a small telescope will show it as a starlike point of light. Its long orbit means it takes years to move through each zodiacal constellation.

ATMOSPHERE AND WEATHER Neptune is a perplexing place. For a CLOUDS OVER NEPTUNE planet so far from the Sun, it has a Neptune’s atmosphere surprisingly dynamic atmosphere that lies in bands, which exhibits colossal storms and super-fast are parallel to the winds. The heat Neptune receives from equator. The bright patches are highthe Sun is not enough to drive its altitude clouds, weather. The atmosphere may be floating above the warmed from below by Neptune’s blue methane layer. internal heat source, and this is the trigger for larger-scale atmospheric changes. The white bands that encircle the planet are cloud cover, produced when the heated atmosphere rises and then condenses, forming clouds. The winds are most ferocious in the equatorial regions, where they blow westward and reach a staggering 1,340 mph (2,160 km/h). Gigantic, dark, stormlike features accompanied by bright, highaltitude clouds appear and then disappear. One, the Great Dark Spot, was seen by Voyager 2 in 1989. When the Hubble Space Telescope looked for the storm in 1996, it had disappeared. methane and trace gases 3% hydrogen 79%

helium 18%

COMPOSITION OF ATMOSPHERE

Neptune’s atmosphere is made mostly of hydrogen. But it is the methane that gives the planet its deep blue color, absorbing red light and reflecting blue.

RINGS AND MOONS

THE RINGS OF NEPTUNE

Two Voyager 2 images placed together reveal Neptune’s ring system. The two bright rings are Adams and Le Verrier. The faint Galle ring is innermost, and the diffuse band, Lassell, is visible between the two bright ones.

NEPTUNE’S MOONS Nereid 222.7

Laomedeia 911.8

Halimede 633.4

Psamathe 1,887.3 Neso 1,880.5

Sao 906.6

1 radius +

Despina 2.12 Naiad 1.95 Thalassa 2.02

250

500

750

1,000

1,250

1,500

1,750

2,000

Galatea 2.50 Proteus 4.75 Larissa 2.97

Triton 14.33

1

Scale in radii of Neptune 1 radius = 15,380 miles (24,766 km)

TH E SO LA R S Y S TE M

The first indication that Neptune has a ring system came in the 1980s, when stars were seen to blink on and off near the planet’s disk. Intriguingly, Neptune seemed to have ring arcs. The mystery was solved when Voyager 2 discovered that Neptune has a ring system with an outer ring so thinly populated that it does not dim starlight but contains three dense regions that do. Neptune has five sparse yet complete rings; moving in from the outer Adams ring, they are Arago, Lassell, Le Verrier, and Galle. A sixth, unnamed partial ring lies within Adams. The rings are made of tiny pieces, of unknown composition, which together would make a body just a few miles across. The material is believed to have come from nearby moons. Four of Neptune’s 13 moons are within the ring system. It is one of the moons, Galatea, that prevents the arc material from spreading uniformly around the Adams ring. Only one of the 13, Triton, is of notable size. Triton and Nereid were discovered before the days of space probes. Five small moons have been discovered since 2002, and more will probably be found.

206

NEPTUNE’S MOONS Neptune has only one major moon—Triton. All its other satellites are small and can be described as inner or outer moons depending on whether they are closer to or farther from Neptune than Triton. The six inner moons were discovered by analysis of Voyager 2 data in 1989. The moons are named after NEPTUNE AND TRITON This image of the crescent moon characters associated with the Roman of Triton below the crescent of Neptune was captured by Voyager 2 god of the sea, Neptune, or his Greek counterpart, Poseidon. as it flew away from the planet. INNER MOON

INNER MOON

Larissa

Proteus

DISTANCE FROM NEPTUNE ORBITAL PERIOD LENGTH

45,617 miles (73,458 km)

0.55 Earth days

134 miles (216 km)

Larissa is the fifth moon from Neptune, lying outside the ring system. The moon was first spotted from Earth in 1981, but astronomers eventually decided that it was a ring arc circling Neptune. In late July 1989, a Voyager 2 team of astronomers confirmed that it is, in fact, an irregularly shaped, cratered moon. It was named after a lover of Poseidon.

DISTANCE FROM NEPTUNE ORBITAL PERIOD LENGTH

73,059 miles (117,647 km)

1.12 Earth days

273 miles (440 km)

The most distant of the inner moons from Neptune, Proteus is also the largest of the six—their size increases with distance. It has an almost equatorial orbit, speeding around Neptune in less than 27 hours. Its visible surface has extensive cratering, but just one major feature stands out: a large, almost circular depression measuring 158 miles (255 km) across, with a rugged floor. Proteus was the first of the six inner moons to

be discovered by Voyager 2 scientists. It was detected in mid-June 1989, within two months of the probe’s closest approach to Neptune, allowing the observation sequence to be changed. The images subsequently recorded by Voyager 2 revealed a gray, irregular but roughly spheroid moon that reflects 6 percent of the sunlight hitting it. The moon was later named Proteus after a Greek sea god. rim of circular depression

TWO VIEWS

IRREGULARLY SHAPED MOON

The first image of Proteus (far right) shows the moon half-lit. The second was taken closer in (the black dots are a processing artifact).

cratered surface

MAJOR MOON OUTER MOON

OUTER MOON

Halimede

Nereid DISTANCE FROM NEPTUNE

3.4 million miles

ORBITAL PERIOD

TH E S O LA R S YS TEM

DIAMETER

DISTANCE FROM NEPTUNE

9.7 million miles

(15.7 million km)

(5.5 million km) 360.1 Earth days

211 miles (340 km)

Nereid was discovered on May 1, 1949 by the Dutch-born astronomer Gerard Kuiper, while working at the McDonald Observatory in Texas. Little is still known about this moon. Voyager 2 flew by at a distance of 2.9 million miles (4.7 million km) in 1989 and could take only a lowresolution image. Nereid’s outstanding characteristic is its highly eccentric and inclined orbit, which takes the moon out as far as about 5.9 million miles (9.5 million km) from Neptune and to within just 507,500 miles (817,200 km) at its closest approach. BEST VIEW

Voyager 2 revealed Nereid to be a dark moon, reflecting only 14 percent of the sunlight it receives.

ORBITAL PERIOD DIAMETER

1,874.8 Earth days

30 miles (48 km)

Halimede was discovered by an international team of astronomers who were carrying out a systematic

search for new Neptunian moons. Their task was not easy because moons as small and as distant as Halimede are extremely difficult to detect. Halimede follows a highly inclined and elliptical orbit. The origin of the irregular outer moons, which now number five, is unknown. More may be found, since these moons could be the result of an ancient collision between a former moon and a passing body such as a Kuiper Belt object.

EXPLORING SPACE

LOOKING FOR NEW MOONS A team of astronomers announced the discovery of three new moons, including Halimede, on January 13, 2003. They had taken multiple images of the sky around Neptune

from two sites in Hawaii and Chile. The images were combined to boost the signal of faint objects. The new moons showed up as points of light against the background of stars, which appeared as streaks of light.

Triton DISTANCE FROM NEPTUNE ORBITAL PERIOD DIAMETER

1,681 miles (2,707 km)

Triton was the first of Neptune’s moons to be discovered, just 17 days after the discovery of the planet was announced. William Lassell (see panel, right) used the coordinates published in The Times to locate Neptune in early October 1846. On October 10, he found its biggest moon, using the 24-in (61-cm) reflecting telescope at his observatory in Liverpool, England. The moon was named Triton after the sea-god son of Poseidon. The Voyager 2 flyby nearly 143 years later revealed most of what is now known about this icy world.

MAUNA KEA OBSERVATORY, HAWAII

The Canada-France-Hawaii Telescope used in the search is at Mauna Kea. The other site was the Cerro Tololo Inter-American Observatory in Chile.

220,306 miles (354,760 km)

5.88 Earth days

SMOOTH PLAIN

The 185-mile- (300km-) wide Ruach Planitia is in the cantaloupe terrain. It may be an old impact crater that has been filled in.

NEPTUNE

207

ICY SURFACE

The cantaloupe terrain is at the top of this image. The pink color of the south polar cap may come from compounds formed when methane ice reacts with sunlight.

WILLIAM LASSELL

Triton is by far the largest of Neptune’s moons and is bigger than Pluto. It follows a circular orbit and exhibits synchronous rotation, so the same side always faces Neptune. Peculiarly for such a large moon, Triton is in retrograde motion,

Triton’s south polar region is seen head-on in this image. A band of bluish material extends out from the central polar cap into the equatorial region. It is probably fresh nitrogen frost or snow redistributed by the wind. mottled crust

SOUTHERN HEMISPHERE

Three Voyager 2 images were combined to produce this almost full-disk image of Triton. From a distance, the southernhemisphere terrain appears mottled.

English businessman William Lassell (1799–1880) used the profits from his brewery to fund his passion for astronomy. He designed and built large reflecting telescopes that were the finest of the day. He made his observations first from his home in Liverpool, England, then from the island of Malta. In addition to Triton, Lassell discovered the Uranian moons Ariel and Umbriel, and Saturn’s moon Hyperion.

TH E S OL A R S Y S TE M

POLAR PROJECTION

traveling in the opposite direction of Neptune’s spin. This could be a clue to its origin. Triton may have formed elsewhere in the solar system and been captured by Neptune. The moon’s mix of two parts rock to one part ice is differentiated into a rocky core, a possibly liquid mantle, and an ice crust. Its geologically young, icy surface has few craters and displays a range of features. An area of linear grooves, ridges, and circular depressions is nicknamed the cantaloupe after its resemblance to a melon’s skin. Dark patches mark the south polar region. These form when solar heat turns subsurface nitrogen ice into gas. This erupts through surface vents in geyserlike plumes, which carry dark, possibly carbonaceous dust into the atmosphere before depositing it on Triton’s surface.

208

THE KUIPER BELT AND THE OORT CLOUD

THE KUIPER BELT AND THE OORT CLOUD

Classical Kuiper Belt

CHIRON

Discovered in 1977, Chiron is the prototype of a group of icy bodies following orbits around those of Saturn and Uranus. Known as Centaurs, they are thought to be Scattered Disk Objects that have been pulled inward by interactions with Neptune’s gravity. They may go on to become short-period comets.

QUAOAR

The multiple exposures in this image show Quaoar moving across the sky. Discovered in 2002, it has an estimated diameter of around 730 miles (1,170 km), about half that of Pluto, but Quaoar is much denser than Pluto, indicating that it contains more rock than ice.

LOCATION OF THE KUIPER BELT

The Kuiper Belt extends out from the orbit of Neptune to about 9.3 million miles (15 billion km) from the Sun. It has two subregions: the Classical Kuiper Belt, extending out to about 4.7 billion miles (7.5 billion km), and the Scattered Disk stretching from the Classical Belt to the edge of the entire Kuiper Belt.

THE KUIPER BELT AND ITS CONSTITUENTS The Kuiper Belt is a broad ring of objects that begins around the orbit of Neptune and extends out to roughly 9.3 billion miles (15 billion km) from the Sun. The possibility of such a belt was initially put forward in 1930, soon after the discovery of Pluto (see opposite). The first theoretical models for how such a belt could have formed were proposed in 1943 by British astronomer Kenneth Edgeworth and in 1951 by Gerard Kuiper (see panel, below). For this reason, the belt is sometimes known as the Edgeworth–Kuiper Belt, or EKB. However, the belt remained purely theoretical until 1992, when astronomers identified a small body with a diameter of about 100 miles (160 km), now known as 1992 QB1. This was the first confirmation that there were other objects in addition to Pluto in the space beyond Neptune, and since then about a thousand more such objects have been discovered. The Kuiper Belt as a whole can be split into an inner zone called the Classical Kuiper Belt and an outer zone called the Scattered Disk. The Classical Kuiper Belt extends out to about 4.7 billion miles (7.5 billion km) from the Sun, and is relatively densely populated with objects that have roughly circular orbits. The drop in density at its outer edge is known as the Kuiper Cliff. Beyond this is the Scattered Disk, which is relatively sparsely populated with objects that have more eccentric and tilted orbits.

TH E S O LA R S YS TEM

GERARD KUIPER

EXTRA-SOLAR DEBRIS DISC

Several Kuiper Belt-like structures have been found around other stars that are thought to be debris left over from the processes of planet formation. The disc around the billion-year old HD 53143 (shown right), a cool star about 60 lightyears from Earth, stretches to around 16.5 billion km (10.2 billion miles) from its central star— roughly the same diameter as our Kuiper Belt and Scattered Disc.

Neptune’s orbit

Scattered Disk

BEYOND THE ORBITS

of the giant planets the solar system is 38–39 Gravity, motion, and orbits surrounded by billions of small, 102–103 The family of the Sun icy worlds, separated into distinct Comets 212–13 groups by their composition and orbits. The innermost region, made up of the doughnutshaped Classical Kuiper Belt and the looser, more chaotic Scattered Disk, consists of large numbers of ice dwarfs. Some of these icy bodies are the size of small planets, and one—Pluto—was originally classified as a planet in its own right. Beyond lies an enormous halo of smaller icy bodies known as the Oort Cloud. Believed to contain trillions of objects, the Oort Cloud is the source of many of the comets that visit the inner solar system. 26–27 Celestial objects

Kuiper Cliff

Gerard Kuiper (1905–73) was one of the most influential planetary scientists of the 20th century. After studying astronomy at the University of Leiden in the Netherlands, he moved to the United States in 1933. He founded the Lunar and Planetary Institute at Tucson, Arizona, in 1960, and later worked on early planetary probes. He discovered the moons Miranda and Nereid, and was also the first to identify carbon dioxide in the atmosphere of Mars. In 1951, he proposed the existence of what we now call the Kuiper Belt, although he believed that its existence had been a short-lived phase of the early solar system.

THE KUIPER BELT AND THE OORT CLOUD

209

EXPLORING SPACE

Sun

Uranus’s orbit

SEARCHING FOR A PLANET

Pluto’s orbit

Pluto was discovered as the result of a deliberate hunt for a “Planet X,” which in the early 20th century was thought to affect the orbits of Uranus and Neptune. American astronomer Clyde Tombaugh began his attempt to find this planet at the Lowell Observatory, Arizona, in 1929. His method involved photographing the same area of sky a few days apart and comparing the two images to look for any objects that had moved. On January 23, 1930, Tombaugh took a long exposure of the Delta Geminorum region. On January 29 he imaged the area again, and one “star” in his plates (indicated by the red arrow) had moved. He had discovered Pluto. It later became clear that Pluto was too small to be Planet X, and astronomers today realize there is no need for a Planet X in our models of the solar system.

PLUTO Discovered by US astronomer Clyde Tombaugh in 1930 (see panel, right), Pluto was for a long time classified as a planet in its own right, but today it is acknowledged as the first Kuiper Belt Object to be discovered—one that is unusually large, bright, and relatively close to the Sun. Pluto’s 248-year orbit ranges between about 2.7 billion miles (4.4 billion km) and 4.6 billion miles (7.4 billion km) from the Sun, meaning that Pluto sometimes lies closer in than Neptune (most recently between 1979 and 1999). However, the pronounced tilt of Pluto’s orbit (at an angle of 17.1° to the ecliptic), combined with the fact that it sits in a resonant orbit with Neptune make close encounters between the two impossible. Pluto’s spin axis is tilted at 122° to the vertical, which means that it spins in the opposite direction to Earth. Pluto is about 1,430 miles (2,300 km) across and has several moons, the largest of which, Charon, is half the size of Pluto itself. Pluto’s surface is covered in a variety of chemical ices, and when the planet is at its closest to the Sun some of these surface ices evaporate to form a thin atmosphere. Scientists have speculated that Pluto may look similar to Neptune’s large moon Triton (see pp.206–207) and that it could even display similar geological activity.

PLUTO AND ITS MOONS

Hydra

Pluto has four known moons: Charon, Hydra, Nix, and P4 (also known as S/2011 P1). Charon is by far the largest, with a diameter of about 746 miles (1,200 km). Hydra is about 71 miles (114 km) across, and Nix is about 56 miles (90 km) across. P4, discovered in 2011, is the smallest, with an estimated diameter of only 8–21 miles (13–34 km). P4 Nix Pluto icy crust Charon

mantle rich in water ice

large rocky core

SURFACE OF PLUTO

INTERIOR OF PLUTO

Pluto’s surface ices, seen here in a Hubble Space Telescope image, are dominated by frozen nitrogen, with traces of methane and carbon monoxide. Impurities in the ice are thought to be responsible for the mottled coloring of its surface.

Pluto is thought to consist of a rocky core, which makes up about 70 percent of the planet’s diameter, surrounded by a mantle of water ice and a thin, icy crust. Heat from the core may help sustain a thin layer of liquid water between the core and mantle.

This image of the Pluto–Charon system was taken by one of the 26.9 ft (8.2 m) telescopes at Paranal Observatory, Chile. Charon was discovered in 1978 by James Christy of the US Naval Observatory, Arizona, who noticed that Pluto’s image became elongated periodically. He realized that this was because Pluto has a moon. Charon orbits Pluto at a distance of 10,890 miles (17,530 km).

TH E S OL A R S Y S TE M

GROUND-BASED IMAGE

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THE KUIPER BELT AND THE OORT CLOUD

CLASSICAL KUIPER BELT OBJECTS The objects of the Classical Kuiper Belt, often called KBOs, form several distinct groups that have different compositions and probably originate from different parts of the solar system. One distinction is between “cold” and “hot” KBOs. Despite their name, these groups are identified not by differences in their surface temperatures but by the shape and tilt of their orbits. Cold KBOs have relatively circular orbits with shallow tilts. They also have reddish surfaces, indicating the presence of methane ice. Hot KBOs, such as Makemake, follow more eccentric and tilted orbits and have bluish white surfaces. Cold KBOs are thought to have originated in roughly the same region where they currently orbit, while hot KBOs probably originated closer to the Sun than they are now. A third group, known as Plutinos, occupy stable orbits in a 2:3 resonance with Neptune (that is, they orbit the Sun twice for every three orbits of Neptune). This configuration protects them from Neptune’s gravitational influence and ensures their orbits remain stable. However, the Plutinos, which include Haumea and Pluto itself, are not considered to be Classical KBOs by some astronomers.

OORT CLOUD

The Oort Cloud is thought to consist of two distinct regions: a spherical, sparsely populated outer cloud, and a doughnut-shaped inner cloud. Comets in the more densely populated inner cloud are frequently ejected into the outer cloud, and help keep it replenished.

Sun

Kuiper Belt

MAKEMAKE

Discovered in 2005, Makemake has an estimated diameter of 845–920 miles (1,360–1,480 km), about two-thirds the size of Pluto. With a temperature of only about -405ºF (-243ºC), Makemake’s surface is covered with methane, ethane, and possibly nitrogen ices.

HAUMEA

With a long axis of about 1,218 miles (1,960 km) and a short axis only half this length, Haumea is unusually elongated for a KBO. It also has a very short rotational period, spinning on its axis once every four hours. It was discovered in 2004.

TH E S O LA R S YS TEM

SCATTERED DISK OBJECTS Beyond the Classical Kuiper Belt is another distinct group of objects, known as Scattered Disk Objects (SDOs). These SDOs move around the Sun in eccentric, often highly tilted orbits that sometimes cross the Classical Belt but also venture much further out, to 9.3 billion miles (15 billion km) from the Sun or more. They are thought to have originated closer to the Sun and been ejected outwards by the gravitational influence of the outer planets. SDOs are still affected by Neptune’s gravity, and the Scattered Disk is thought to be the source of Centaur objects, such as Chiron, as well as some comets. The largest known SDO is Eris, discovered in 2005. According to initial estimates, Eris is similar in size to Pluto, and it was soon found to have a moon of its own, Dysnomia. Astronomers faced a choice of either promoting Eris to an official 10th planet of the solar system or demoting Pluto, since it was clearly just a large KBO. They chose the latter option and introduced a new category—dwarf planet—for objects that have planetlike features but lack sufficient gravity to clear their neighboring region of other objects.

typical elongated orbit of long-period comet

few comets lie in the region between the inner and outer Oort Cloud

ERIS AND DYSNOMIA

Dysnomia

Eris

orbit of Dysnomia

On September 10, 2005, astronomers using the 32.8ft (10m) Keck telescope in Hawaii discovered that Eris has a moon (seen to the left of Eris), now named Dysnomia. This moon orbits Eris about once every 16 days. Together, Eris and Dysnomia move around the Sun in a highly eccentric orbit that lasts 557 years.

THE KUIPER BELT AND THE OORT CLOUD

THE OORT CLOUD comet’s orbit takes it to the edge of the Oort Cloud

Surrounding the solar system beyond the Kuiper Belt lies an enormous cloud of long-period comets known as the Oort Cloud. Its outer reaches extend to almost a light-year from the Sun, and it is thought to contain trillions of objects with a total mass of roughly five Earths. The Oort Cloud is impossible to observe directly, although there is strong evidence for it from the orbits of comets that pass through the inner solar system. Its existence was first suggested by Estonian astronomer Ernst Öpik in 1932, but it was also proposed independently by Jan Oort (see panel, right) in 1950. The comets in the Oort Cloud are thought to have originated much closer to the Sun, in the region where the giant planets now orbit. However, early in the solar system’s history, as the giant planets migrated toward their current positions, close encounters with these planets pushed enormous numbers of the comets into highly elliptical orbits. In the outer solar system, these comets were only weakly bound by the Sun’s gravity, so tidal forces from other stars and the Milky Way itself were able to act on them, gradually “circularizing” their orbits. Today, similar tidal effects occasionally knock comets out of the Oort Cloud toward the Sun. However, according to other theories, some Oort Cloud comets might have begun their lives in orbit around other stars and were later captured by the Sun’s gravity.

211

JAN HENDRIK OORT Jan Oort (1900–92) was born in Franeker, the Netherlands, and spent most of his career at the University of Leiden, also in the Netherlands. Oort is mostly remembered for his idea that the solar system is surrounded by the vast symmetrical cloud of comets that was named after him. He is also famous as a pioneer of radio astronomy, for discovering the rotation of the Milky Way and estimating its distance and the direction of its centre from Earth, and for discovering evidence that the universe contains “missing mass” (now known as dark matter).

LONG-PERIOD COMET

Long-period comets, such as Hyakutake (left), typically approach the inner solar system from all directions and at high speeds, indicating that they come from a spherical region that surrounds the Sun at a vast distance—the Oort Cloud.

SEDNA comet orbiting close to the plane of the solar system

DISTANT OBJECT inner cloud outer cloud

When discovered on 14 November 2003, Sedna was nearly 90 times farther from the Sun than Earth, making it the most distant solar system object then observed. Sedna takes approximately 11,400 Earth years to orbit the Sun

Sun Kuiper Belt

Sedna’s closest approach to the Sun (perihelion) will be in 2076

Sedna takes about 11,400 years to complete one orbit around the Sun. It will be at perihelion in 2076, about 7.1 billion miles (11.4 billion km) from the Sun, but spends most of its orbit between the Scattered Disk and the inner Oort Cloud.

Sedna will reach aphelion (farthest point from the Sun) in about 7776

TH E S OL A R S Y S TE M

SEDNA’S ORBIT Pluto

In 2003, astronomers searching for objects in the region of space beyond Neptune discovered a world about 8.4 billion miles (13.5 billion km) from the Sun but moving in an eccentric orbit that takes it out to a maximum distance of 87.1 billion miles (140.2 billion km). This was the most distant object yet found in the solar system. With an estimated surface temperature of -436°F (-260°C), it was also the coldest solar system body, and so it was named after the Inuit goddess of the Arctic Ocean, Sedna. Some astronomers believe that Sedna could offer our first glimpse of an object from the inner Oort Cloud. However, its orbit is unusual even for an object from the innermost part of the Cloud, suggesting that it must have been disrupted in the past. Sedna’s orbit is too remote for it to have been influenced by Neptune, but other possible explanations include disruption RED BODY by the gravity of other stars, or Sedna’s diameter is estimated at even by the influence of a large, 750–1,000 miles (1,200–1,600 km), as yet undiscovered planet far and it has a dark red surface, as beyond Neptune. shown in this artist’s impression.

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COMETS

COMETS

SPECTACULAR SIGHT

COMETS PRODUCE A STRIKING

celestial spectacle when they enter the inner solar system. Their 208–11 The Kuiper Belt and Oort Cloud small nuclei become surrounded by a bright Meteors and meteorites 220–21 cloud, or coma, of dust and gas about 60,000 miles (100,000 km) across. Large comets that get close to the Sun also produce long, glowing tails that can extend many tens of millions of miles into space and are bright enough to be seen in Earth’s sky. 38–39 Gravity, motion, and orbits

Most comets are only discovered when they are bright enough to glow in Earth’s sky. Comet Hale–Bopp was discovered in late July 1997 and could be seen for several weeks afterward. It will return to Earth’s sky again around AD 5400.

ORBITS Cometary orbits divide into two classes. Short-period comets orbit the Sun in the same direction as the planets. Most have orbital periods of about seven years, and get no farther from the Sun than Jupiter. Short-period comets were captured into the inner solar system by the gravitational influence of Jupiter. If they remain in these small orbits, they will decay quickly. Some, however, will be ejected by Jupiter into much larger orbits,and then possibly recaptured. Intermediate- and long-period comets have orbital periods greater than 20 years (see p.214). Their orbital planes are inclined at random to the plane of the solar system. Many of these comets travel huge distances into the interstellar regions. Most of the recorded comets get close to the Sun, where they develop comae and tails and can be easily discovered. There are vast numbers of comets on more distant orbits that are too faint to be found. URANUS

COMET ORBITS

All the comets shown here pass very close to the Sun and until recently were too faint to be observed when they were at the far ends of their orbits. Encke is a short-period comet and orbits in the plane of the solar system. The others are intermediateand long-period comets.

SWIFT–TUTTLE Orbital period about 135 years

SATURN EARTH HALLEY’S COMET Orbital period about 76 years

MARS SUN

ENCKE Orbital period 3.3 years

TH E S O LA R S YS TEM

JUPITER

TEMPEL–TUTTLE Orbital period 32.9 years HYAKUTAKE Orbital period about 30,000 years

HALE–BOPP Orbital period 4,200 and 3,400 years

COMETS

STRUCTURES

crust of dark dust

The fount of all cometary activity is a lowdensity, fragile, irregularly shaped, small nucleus that resembles a “dirty snowball.” The dirt is silicate rock in the form of small dust particles. The snow is mainly composed of water, but about 1 in 20 molecules are more exotic, being carbon dioxide, carbon monoxide, methane, ammonia, or more complex organic compounds. The nucleus is covered by a thin, dusty layer, which is composed of jets of gas cometary material that has lost and dust are snow from between its cracks and released from surface when crevices. The snow is converted heated by the Sun directly from the solid into the gaseous state by the high level of solar radiation the comet receives when it is close to the Sun.

NUCLEUS

The central part of Comet Borrelly’s elongated nucleus has a smooth terrain, but the more “mottled” regions consist of steep-sided hills that are separated by pits and troughs.

LIFE CYCLES

CRATER CHAIN

This 120-mile- (200-km-) long chain of impact craters, named Enki Catena, is on Ganymede, the largest of Jupiter’s moons. It is likely that Ganymede was struck by 12 or so fragments of a comet that had just been pulled apart by tidal forces as it passed too close to Jupiter.

COMET SOHO-6

FRED WHIPPLE

bright side faces the Sun

impact crater

snow and dust structure inside nucleus

CROSS-SECTION

The nucleus has a uniform structure, consisting of many smaller “dirty snowballs.” The surface dust layer is only a few inches thick and appears dark because it reflects little light. The strength of the whole structure is negligible. Not only do tidal forces pull comets apart, but many simply fragment at random.

Fred Whipple (1906–2004) was an astronomy professor at Harvard University and the director of the Smithsonian Astrophysical Observatory from 1955 to 1973. In 1951, he introduced the “dirty snowball” model of the cometary nucleus, in which the snowball spins. As the Sun heated one side, its heat was slowly transmitted down to the underlying snows, which eventually turn straight to gas. This resulted in a jet force along the cometary orbit which either accelerated or decelerated the nucleus depending on the direction of its spin.

dust tail is curved

gas tail is straight and narrow

A comet spends the vast majority of its life in a dormant, deep-freeze state. tails shrink as the Activity is triggered by an increase in tails are comet moves away longest close temperature. When the comet gets from the Sun to the Sun closer to the Sun than the outer part of Sun perihelion the Main Belt (see p.170), frozen carbon dioxide and carbon monoxide in the a comet’s tail always points away nucleus start to sublime (that is, they pass from the Sun directly from the solid to the gaseous state). Once the comet is inside the orbit of Mars, it is hot enough for water to join in the tails grow as the activity. The nucleus quickly surrounds itself with comet travels toward the sun an expanding spherical cloud of gas and dust, called a coma. The coma is at its maximum size when the comet is closest to the Sun. A comet that passes through the inner solar system will lose the equivalent of a 6-ftnaked (2-m-) thick layer from its surface. The comet moving away from nucleus the Sun is thus smaller than it was on its approach. Mass is lost every time a comet passes perihelion. Borrelly, for example, orbits the Sun aphelion about every seven years. If it stays on the same orbit, its 2-mile- (3.2-km-) wide nucleus will be reduced to nothing in COMETARY TAILS about 6,000 years. Comets are transient members of the inner As a comet nears the Sun, it develops two solar system. They are soon dissipated by solar radiation. Large tails. The curved tail is formed of dust that is cometary dust particles form a meteoroid stream around the pushed away by solar radiation. The straight orbit. Gas molecules and small particles of dust are just blown tail consists of ionized gas that has been blown away from the coma by the solar wind. away from the Sun and join the galactic disk. HALLEY’S TAIL

These 14 images of Halley’s Comet were taken between April 26 and June 11, 1910, around the time it passed perihelion. An impressive tail was produced and dissipated in just seven weeks of its 76-year orbit.

TH E S OL A R S Y S TE M

Large numbers of sungrazing comets have been discovered by the SOHO satellite. Here, Soho-6 is seen as an orange streak, at left, approaching the masked Sun.

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214

COMETS

COMETS There are billions of comets at the edge of the solar system, but very few have been observed, since they are bright enough to be seen in Earth’s sky only when they travel into the inner solar system and approach the Sun. Nearly 2,000 comets have been recorded and their orbits calculated so far. About 200 of the cataloged comets are periodic, having orbital periods of less than 20 years (short period) COMET HALE–BOPP Caught in the evening sky above or between 20 and 200 years (intermediate Germany in 1997, Hale–Bopp, one period). Most, but not all, comets are named of the brightest comets of the 20th after their discoverers. century, clearly has two tails. INTERMEDIATE-PERIOD COMET

Ikeya–Seki CLOSEST APPROACH TO THE SUN

LONG-PERIOD COMET

Great Comet of 1680 290,000 miles

(470,000 km)

CLOSEST APPROACH TO THE SUN

580,000 miles

(940,000 km)

ORBITAL PERIOD

184 years

ORBITAL PERIOD

9,400 years

FIRST RECORDED

September 8, 1965

FIRST RECORDED

November 14, 1680

This comet is named after the two amateur Japanese comet hunters, Ikeya Kaoru and Seki Tsutomu, who discovered it independently (and within five minutes of each other) in 1965. On October 21, 1965, as it passed perihelion, the comet was so bright that it was visible in the noon sky only 2 degrees from the Sun. Tidal forces then caused the nucleus to split into three parts. Ikeya–Seki faded quickly as it moved away from the Sun, but the tail grew until it extended over 60 degrees across the sky. At this stage it was 121 million miles (195 million km) from the Sun.

This comet has two great claims to fame. It was the first comet to be discovered by telescope and the first to have a known orbit. Some 70 years after the telescope was invented, the German astronomer Gottfried Kirch found the comet by accident when observing the Moon in 1680. The orbit was calculated by the English mathematician

Isaac Newton using his new theory of universal gravity, and the results were published in his masterpiece Principia in 1687. The comet is a sungrazer and was seen twice: first, as a morning phenomenon, when it was approaching the Sun; and subsequently in the evenings, when it was receding. Newton was the first to realize that these apparitions were of the same comet. The English physicist Robert Hooke noticed a stream of light issuing from the nucleus. This was the first description of jets of material emanating from active areas. GREAT COMETS

Great comets, such as this 1680 comet, are extremely bright and can be very startling when they appear.

EXPLORING SPACE

COMET ORBIT Isaac Newton made observations of the Great Comet of 1680. At the time, a conventional view held that comets traveled in straight lines, passing through the solar system only once. Based on his observations, Newton realized that he had seen a comet traveling around the Sun on a parabolic curve. In 1687, in the Principia, he used his study of comets and other phenomena to confirm his law of universal gravitation. He also showed how to calculate a comet’s orbit from three accurate observations of its position. Using Newton’s laws, Edmond Halley successfully predicted the return of the comet named after him.

SUNGRAZER

Ikeya–Seki is a sungrazer and passed within just 290,000 miles (470,000 km) of the Sun’s surface in 1965. It is one of over 1,000 comets in the Kreutz sungrazer family. NEWTON’S ORBIT SKETCH

INTERMEDIATE-PERIOD COMET

Swift–Tuttle CLOSEST APPROACH TO THE SUN

88 million miles

TH E S O LA R S YS TEM

(143 million km) ORBITAL PERIOD

About 135 years

FIRST RECORDED

July 16, 1862

After Swift–Tuttle’s discovery in 1862, calculations of its orbit established the relationship between comets and meteoroid streams. Every August, the Earth passes through a stream of dust particles that produces the Perseid meteor shower, named after the constellation from which the shooting stars appear to be emanating. In 1866 PERSEIDS

It takes about two weeks for the Earth to pass through this meteoroid stream. The peak rate is on August 12, at about 50 visible meteors per hour.

PERIODIC COMET

Swift–Tuttle was discovered independently by American astronomers Lewis Swift and Horace Tuttle in 1862. This optical image was taken in 1992, when the comet approached the Sun once again.

Giovanni Schiaparelli (see p.220), the director of the Milan Observatory in Italy, calculated the mean orbit of the Perseid meteoroids. He immediately realized that this orbit was very similar to that of Comet Swift–Tuttle, which intersects Earth’s path. He concluded that meteoroid streams were produced by the decay of comets, the meteoroids being no more than cometary dust particles, a fraction of a gram in mass, hitting the Earth’s upper atmosphere at velocities of about 134,000 mph (216,000 km/h). About the same

number of Perseid meteors are seen each year, so the dust must be evenly spread around the cometary orbit. This uniformity takes a long time to come about. Swift–Tuttle must have passed the Sun on the same orbit a few hundred times to produce this effect. Comets are decaying, but they have to pass through the inner solar system a thousand times or so before they are whittled down to nothing.

COMETS LONG-PERIOD COMET

West CLOSEST APPROACH TO THE SUN

18 million miles

(29 million km) ORBITAL PERIOD

About 500,000 years

FIRST RECORDED

November 5, 1975

This comet was one of the first to have a spectrum of hydroxyl (OH) detected. Comet West was discovered by Richard West, an astronomer at the European Southern Observatory, when he examined a batch of photographic plates taken by the 39.4-in (100-cm) Schmidt telescope at La Silla, Chile. It was on the inner edge of the asteroid belt, on its way toward the Sun. At the time, the comet was visible only from the Southern Hemisphere. During February 1976, the comet not only moved into the northern sky, but also

brightened impressively. By the end of February, it was easily visible to the naked eye. It was closest to the Sun on February 25. Just before it reached perihelion, the nucleus of the comet broke into two. A week or so later, it split further, and the comet eventually broke into four pieces. These could be seen gradually moving away from each other throughout March, and they all developed a separate tail. Rocket-borne spectrometers were used to investigate Comet West. These looked at ultraviolet radiation, a region of the spectrum containing hydroxyl bands. These are important because cometary snow contains water molecules that divide into hydrogen (H) and hydroxyl (OH) ions when they are released from the nucleus. By studying the comet with spectrometers, it was possible to measure how much water was lost as it approached perihelion.

EARTHGRAZER

When it passed within Earth’s orbit, Hyakutake became one of the brightest comets of the 20th century.

LONG-PERIOD COMET

Hyakutake CLOSEST APPROACH TO THE SUN

21.4 million miles

(34.4 million km) ORBITAL PERIOD

About 30,000 years

FIRST RECORDED

January 30, 1996

This comet became a Great Comet, not (like Hale–Bopp) because the nucleus was big, but because on March 24, 1996, it came within a mere 9 million miles (15 million km) of Earth. It was discovered by the Japanese amateur astronomer Hyakutake Yuji using only a pair of high-powered binoculars. The comet became so bright that large radio-telescope spectrometers could detect minor TELESCOPIC VIEW

In March and April 1996, superb short-exposure photographs of Hyakutake could be obtained using only large telephoto lenses or small telescopes.

SHORT-PERIOD COMET

Encke CLOSEST APPROACH TO THE SUN

32 million miles

(51 million km) ORBITAL PERIOD

3.3 years

FIRST RECORDED

January 17, 1786

Comet Encke was “discovered” in 1786 (by the French astronomer Pierre Méchain), in 1795 (by the Germanborn astronomer Caroline Herschel), and in 1805 and 1818-19 (by the French astronomer Jean Louis Pons). These comets were found to be the same only after orbital calculations in 1819 by the German astronomer Johann Encke, who then predicted its

constituents in the coma, such as a compound of water and deuterium (HDO) and methanol (CH3OH). Hyakutake was the first comet to be observed to emit X-rays. Subsequently, it was found that other comets are also sources of X-rays, the rays being produced when electrons in the coma are captured by ions in the solar wind. On May 1, 1996, the Ulysses spacecraft detected Hyakutake’s gas tail when 355 million miles (570 million km) from the nucleus. This is the longest comet tail to be detected to date. Sections of Hyakutake’s gas tail have disconnected due to interactions between magnetic fields in the solar wind and the tail.

The striations that can be seen in Comet West’s tail are known as synchronic bands. Each band is produced by a puff of dust emitted from the spinning nucleus.

Not all comets have tails. Some, such as Encke, just have a dense spherical envelope of gas and dust around the nucleus called the coma. The density of the gas decreases as it flows away from the nucleus. Cometary comae have no boundaries; they just fade away.

TH E S OL A R S Y S TE M

return in 1822. Comet Encke is unusual in that, like Halley’s Comet, it is not named after its discoverer. It has the shortest period of any known comet and has been seen returning to the Sun on over 59 occasions. The orbit is also shrinking in size, for Encke comes back to perihelion about 2.5 hours sooner than it should. Some astronomers have suggested that this is due to the comet plowing through a resistive medium in the solar system. But other comets have returned later than predicted, and the time error has varied from one orbit to the next. Astronomers have realized that the changing orbits were caused by the “jet effect” of gas escaping from the comet’s nucleus. The comet receives a push from the expanding gases and, depending on its direction of spin in relation to its orbit, it is either accelerated or decelerated. COMA

TAIL BANDS

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COMETS HALLEY AGAINST A STAR FIELD

INTERMEDIATE-PERIOD COMET

This photograph was taken from Australia on March 11, 1986, three days before the comet was visited by the Giotto spacecraft.

Halley’s Comet CLOSEST APPROACH TO THE SUN

55 million miles

(88 million km) ORBITAL PERIOD

About 76 years

FIRST RECORDED

240 BC

In 1696, Edmond Halley, England’s second Astronomer Royal, reported to the Royal Society in London that comets that had been recorded in 1531, 1607, and 1682 had very similar orbits. He concluded that this was the same comet returning to the inner solar system about every 76 years, moving under the influence of the newly discovered solar gravitational force. What is more, Halley predicted that the comet would return in 1758. Halley’s Comet was the first periodic comet to be discovered. This indicated that at least some comets were permanent members of the solar system. Orbital analysis has revealed that Halley’s Comet has been recorded 30 times, the first known sighting being in Chinese historical diaries of 240 bc. The last appearance, in 1986, was 30 years after the start of the space age, and five spacecraft visited the comet. The most productive NUCLEUS

Giotto revealed that Halley’s nucleus is 9.5 miles (15.3 km) long. The brightest parts of this image are jets of dust streaming toward the Sun.

was ESA’s Giotto mission. This flew to within 370 miles (600 km) of the nucleus and took the first-ever pictures. Giotto proved that cometary nuclei are large, potato-shaped dirty snowballs and that the majority of the snow is water ice. Halley was about 93 million miles (150 million km) from the Sun when Giotto encountered it. Only about 10 percent of the surface was actively emitting gas and dust at the time. On average, a comet loses a surface layer about 6.5 ft (2 m) deep every time it passes through the inner solar system. At this rate, Halley’s Comet will survive for about another 200,000 years.

MYTHS AND STORIES

CELESTIAL OMEN Some superstitious people regard comets as portents of death and disaster. Before Edmond Halley’s work, all comets were unexpected. They were often compared to flaming swords. England’s King Harold II was worried by the appearance of Halley’s Comet in 1066. But what was a bad omen for him was a good sign for the Norman Duke William, who conquered Harold at Hastings. BAYEUX TAPESTRY

This crewel embroidery beautifully depicts the coma and tail of Halley’s Comet (top left), as seen in 1066. It looks like a primitive rocket spewing out flames.

LONG-PERIOD COMET

Hale–Bopp CLOSEST APPROACH TO THE SUN

85 million miles

TH E S OL A R S Y ST E M

(137 million km)

TWIN TAILS

The two tails of Comet Hale–Bopp shine brightly over the Little Ajo mountains in Arizona shortly after sunset in 1997.

ORBITAL PERIOD

2,530 and 4,200 years

FIRST RECORDED

July 23, 1995

Comet Hale–Bopp was discovered independently and accidentally by the American amateur astronomers Alan Hale and Thomas Bopp, who were looking at Messier objects in the clear skies of the western US (it was close to M70). Later, after the orbit had been calculated, Hale–Bopp was found to be at a distance of over 600 million miles (1 billion km). This is between the orbits of Jupiter and Saturn and is an almost unprecedented distance for the discovery of a nonperiodic comet. The orbit showed that it had been to the inner solar system before, some 4,200 years ago, but because it passed close to Jupiter a few months after discovery, it will return again in about 2,510 years. Hale–Bopp passed perihelion on April 1, 1997. It was one of the brightest comets of the century—not, like Hyakutake, because it came very close to Earth, but simply because it had a huge nucleus, about 22 miles (35 km) across.

COMETS SHORT-PERIOD COMET

SHORT-PERIOD COMET

Giacobini–Zinner CLOSEST APPROACH TO THE SUN

96 million miles

SHORT-PERIOD COMET

Churyumov– Gerasimenko

Borrelly CLOSEST APPROACH TO THE SUN

CLOSEST APPROACH TO THE SUN

6.61 years

FIRST RECORDED

November 1900

121 million miles

(194 million km)

This comet was the first to be investigated in situ. The International Comet Explorer spacecraft flew through the tail about 4,840 miles (7,800 km) from the nucleus on September 11, 1985. The measurements concentrated on the way in which the plasma in the solar wind interacted magnetically with the expanding atmosphere of the comet. In 1946, Earth crossed the comet’s path just 15 days after it had passed. About 2,300 meteors per hour were recorded.

126 million miles

(203 million km)

(155 million km) ORBITAL PERIOD

217

ORBITAL PERIOD

6.59 years

FIRST RECORDED

September 20, 1969

SHRINKING TAIL

This image was taken 82 days after Comet Churyumov-Gerasimenko passed perihelion in 2002. A small tail can still be seen.

In 1969, the Russian astronomer Klim Churyumov was inspecting a photographic plate taken by Svetlana Gerasimenko to see if he could find an image of Comet Comas Solá, and made an exciting new discovery instead. Churyumov–Gerasimenko is a typical short-period comet, staying between the orbits of Mars and Jupiter as it travels around the Sun. It has recently become famous because it is now the target of ESA’s Rosetta mission. This orbiting spacecraft was intended to go to Comet Wirtanen,

but the launch was delayed due to problems with the Ariane 5 rocket. It finally launched on March 2, 2004. Rosetta will go into orbit around Churyumov–Gerasimenko in November 2014, when it is 490 million miles (790 million km) away from the Sun. The comet’s nucleus will be cold and inactive, enabling a small lander, called Philae, to perform a solar system first by touching down on the surface. Rosetta and Philae will then stay with the comet as it travels into the inner solar system and will monitor the way in which the activity “switches on.”

ORBITAL PERIOD

6.86 years

FIRST RECORDED

December 28, 1904

The flyby of NASA’s Deep Space 1 mission on September 22, 2001 revealed that this periodic comet has a nucleus shaped like a bowling pin, about 5 miles (8 km) long. Reflecting on average only 3 percent of the sunlight that hits it, Borrelly has the darkest known surface in the inner solar system. Any ice in the nucleus is hidden below the hot and dry, mottled, sooty black surface.

NUCLEUS

Churyumov–Gerasimenko’s nucleus is shaped like a football and 3 mile (5 km) long. It is much smaller than the bright, white central region of the cometary coma.

GIACOBINI–ZINNER IN 1905

SHORT-PERIOD COMET

Wild 2 CLOSEST APPROACH TO THE SUN

Hemenway

Rahe

Mayo

Left Foot

147 million miles

SHORT-PERIOD COMET

Shoemaker–Levy 9 ORBITAL DISTANCE FROM JUPITER

(236 million km)

56,000 miles

(90,000 km)

ORBITAL PERIOD

6.39 years

ORBITAL PERIOD AROUND JUPITER

FIRST RECORDED

January 6, 1978

FIRST RECORDED

Wild 2 is a relatively fresh comet that was brought into an orbit in the inner solar system as recently as September 1974, when it had a close encounter with Jupiter. It is too faint to be seen with the naked eye, since its nucleus is only 3.4 miles (5.5 km) long. Wild 2’s present path around the Sun takes it very close to the orbits of both Mars and Jupiter. It may oscillate between its present orbit and an orbit with a period of about 30 years that brings it only as close as Jupiter. Wild 2 was

Shoemaker Basin

Walker Right Foot

CLOSE-UP OF NUCLEUS

The surface of the nucleus is covered by steep-walled depressions hundreds of yards (meters) deep. They are mostly named after famous cometary scientists.

chosen for NASA’s Stardust mission (see panel, below) because the spacecraft could fly by at the relatively low speed of 13,600 mph (21,900 km/h), capturing comet dust on the way.

2.03 years

Unlike normal comets, this one was discovered in orbit around Jupiter by the American astronomers Gene and Carolyn Shoemaker and David Levy. Even more remarkably, it was in 22 pieces, having been ripped apart on July 7, 1992, when it passed close to Jupiter. These fragments subsequently crashed into the atmosphere in Jupiter’s southern hemisphere in July 1994 (see

p.181). Observatories all over the world and the Hubble Space Telescope witnessed the sequence of events. The nucleus was originally just over 0.6 miles (1 km) across and was most likely captured by Jupiter in the 1920s.

AEROGEL SHATTERED NUCLEUS

The bright streak at the center of this image (which covers 620,000 miles/1 million km) is the string of nuclei and associated comae.

CAROLYN SHOEMAKER After taking up astronomy at the age of 51 after her three children had grown up, Carolyn Shoemaker (b. 1929) has now discovered over 800 asteroids and 32 comets. She uses the 18-in (46-cm) Schmidt wide-angle telescope at the Palomar Observatory in California. Her patience and attention to detail are vital when it comes to inspecting photographic plates that are taken about an hour apart and then studied stereoscopically. Typically, 100 hours of searching are required for each comet discovery. Carolyn was married to Gene Shoemaker (see p.139).

TH E S OLA R S Y S TE M

THE STARDUST MISSION

Although it has a ghostly appearance, aerogel is solid. It a silicon-based spongelike foam, 1,000 times less dense than glass.

The production of the jets of gas and dust emanating from Borrelly’s nucleus is eroding the surface. There is a possibility that the nucleus will split in two in the future.

March 25, 1993

EXPLORING SPACE

The Stardust spacecraft flew by Wild 2 on January 2, 2004. It has captured both interstellar dust and dust blown away from the comet’s nucleus. Aerogel placed on an extended tennis-racket-shaped collector was used to capture the particles without heating them up or changing their physical characteristics. The craft returned to Earth in 2006 and the collector, stowed in a canister, parachuted to safety in the desert in Utah.

DEEP SPACE 1 IMAGE

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COMETS TEMPLE NUCLEUS

SHORT-PERIOD COMET

Tempel 1 CLOSEST APPROACH TO THE SUN

140 million miles

(226 million km) ORBITAL PERIOD

5.52 years

FIRST RECORDED

April 3, 1867

The potato-shaped nucleus of Comet Tempel 1 was photographed by the Deep Impact probe in July 2005. The impactor hit between the craters at center right.

This comet was first discovered in 1867 by the German astronomer Wilhelm Tempel, but after two reappearances it disappeared because its orbit had been changed by close approaches to Jupiter. Following calculations by British astronomer Brian Marsden in 1963, the comet was rediscovered, and it has been followed ever since as it orbits between Mars and Jupiter. To find out what lies beneath the dusty crust of a comet’s nucleus, NASA launched an ambitious mission to Tempel 1 in 2005. Called the Deep Impact probe, its aim was to punch a crater in the crust and uncover the subsurface ice, which is thought to have survived unchanged since the formation of the solar system. As the probe approached the nucleus of

DEEP IMPACT

A fountain of dust, shown in false color, sprays off the nucleus of Comet Tempel 1. This image was taken on July 4, 2005, about 50 minutes after the comet’s nucleus was hit by the impactor released by Deep Impact.

EXPLORING SPACE

STUDYING COMETS protective shield communications antennae

solar panels STARDUST–NEXT

SHORT-PERIOD COMET

Hartley 2 CLOSEST APPROACH TO THE SUN

98 million miles

TH E S OL A R S Y ST E M

(158 million km) ORBITAL PERIOD

6.47 years

FIRST RECORDED

March 15, 1986

This comet was discovered by British astronomer Malcolm Hartley while he was working at the Schmidt Telescope Unit at Siding Spring Observatory, Australia, in 1986. The nucleus of Comet Hartley 2 has been observed close-up in a flyby from the Deep Impact probe. Following its encounter with Comet Tempel 1 (see above), the Deep Impact probe was sent to take a closer look at Hartley 2. After a journey of five years, it arrived near the comet in November 2010 and flew past it at a distance of just under 435 miles (700 km). The spacecraft was not carrying a second impactor so it could not hit the nucleus. Instead, research concentrated on the comet’s appearance and composition. Deep Impact’s observations revealed that Hartley 2’s nucleus, at

Space-probe exploration of comets began at the last return of Halley’s Comet, in 1986. Since then, probes have brought back samples of dust (Stardust NExT, left) and hit the nucleus (Deep Impact). The next step is to orbit and land on a comet’s nucleus—the mission of the European probe Rosetta. Comet probes are fitted with shields to protect them from the fast-moving specks of dust from the comets.

only about 1.2 miles (2 km) long, was the smallest ever visited by a space probe. The comet is peanut-shaped, with two lobes that are connected by a smoother neck only about ¼ mile (0.4 km) wide. Jets of carbon-dioxide gas shoot out from the two lobes at either end of the nucleus, while water vapor is released from the middle. The levels of gas production also vary as the nucleus rotates over a period of about 18 hours. In addition, for the first time with any comet, the nucleus was seen to be shedding lumps of ice that ranged in size from golfballs to basketballs. Investigation by the Deep Impact probe also revealed larger blocks of ice up to 260 ft (80 m) high on the lobes of nucleus. Although the spacecraft retained the name Deep Impact for this encounter, its extended space mission has been renamed EPOXI. This name comes from a combination of two acronyms: EPOCh, which stands for Extrasolar Planet Observation and Characterization, since its instruments observed a number of stars for evidence of transits by orbiting planets; and DIXI, short for Deep Impact Extended Investigation.

Tempel 1 in July 2005, it released a 820 lb (370 kg) copper impactor into its path. This collided with the nucleus at a speed of over 22,800 mph (36,000 kph), spraying out a fountain of dust and gas. Because the dust was so fine, about the same size as the particles in talcum powder, it appeared very bright—the comet temporarily brightened tenfold as a result, but it was still not visible to the naked eye. Deep Impact observed the ejected material to determine its composition. Most of the gas was steam (water vapor) and carbon dioxide at an initial temperature of over 1,340°F (720°C), resulting from

the heat of the impact. There was so much dust that the crater formed by the impactor was hidden from view. As Deep Impact flew past the comet, it took detailed images of the nucleus, which turned out to be shaped like a potato. It measured about 4¾ miles (7.5 km) long and 3 miles (5 km) across, and rotated every 41 hours. It was very different to the nuclei of other comets that have been seen close up, such as Wild 2 and Borrelly. Surface features were visible, including a plateau fringed by a 66 ft (20 m) cliff, possibly the result of a landslide, and two apparent impact craters, each about 1,000 ft (300 m) wide. The impactor hit the nucleus between these craters. Stardust, the craft that had collected dust samples from Comet Wild 2 (see p.217), was later sent to photograph the crater produced by Deep Impact. Renamed StardustNExT (for New Exploration of Tempel 1), it arrived in 2011 but saw little. It seems that the scar had been covered by dust that fell back onto it.

SPECTACULAR JETS

Huge jets of gas and dust spew from the elongated nucleus of Comet Hartley 2 as seen in this image from the Deep Impact probe. The image was taken on November 4, 2010, when the spacecraft was at it closest to the comet.

COMETS LONG-PERIOD COMET

McNaught CLOSEST APPROACH TO THE SUN

15.9 million miles

(25.5 million km) ORBITAL PERIOD

Will not return

FIRST RECORDED

August 7, 2006

The finest naked-eye comet of recent years was discovered by Scottish astronomer Robert McNaught at Siding Spring Observatory, Australia, during a routine photographic search for near-Earth objects. However, this

object was not near Earth—it was still beyond the Main Belt. Calculations indicated that over the following few months it would approach the Sun and brighten considerably. At that time, no one could have anticipated just how bright it would get. On January 12, 2007, Comet McNaught reached its closest point to the Sun—it was 16 million miles (25.5 million km) away, less than half the distance of Mercury. Over the next couple of days, it was visible to the naked eye. At first, it could be seen low down in evening twilight from

the Northern Hemisphere. Its coma was estimated to be brighter than Venus, making it the brightest since comet Ikeya–Seki of 1965 (see p.214). Comet McNaught then moved too far south to be seen by northern observers, but became prominent in the Southern Hemisphere, sporting a fan-shaped dust tail that arced across the sky. The tail displayed long streaks like those of Comet West in 1976 (see p.215) and was mistaken by some as smoke from a distant fire. At its greatest, Comet McNaught’s tail was estimated to be 90 million miles

219

(150 million km) long, the same as the distance from Earth to the Sun. Comet McNaught remained visible to the naked eye into February. Its passage through the inner solar system changed its orbit, and it is now on a path that will take it out of the solar system, never to return.

DUSTY TAIL

Comet McNaught spread its magnificent tail over the southern sky in January 2007. It is seen here above the Pacific Ocean. The light source at lower right is the Moon.

SHORT-PERIOD COMET

Lovejoy CLOSEST APPROACH TO THE SUN

515,000 miles

(829,000 km)

Comet Lovejoy (circled) emerges from its passage through the Sun’s inner corona as seen by NASA’s Solar Dynamics Observatory.

565 years

FIRST RECORDED

November 27, 2011

This sungrazer comet was discovered by an Australian amateur astronomer, Terry Lovejoy, less than three weeks before its closet approach to the Sun. Sungrazers are comets that skim so close to the Sun they either evaporate in the intense heat or they crash into its surface. They are usually seen only by telescopes on board satellites that monitor the region around the Sun, such as the Solar and Heliospheric Observatory (SOHO, see p.105). In December 2011, Comet Lovejoy not only defied predictions by surviving passing so close to the Sun but emerged to become a brilliant object that could be seen from Earth. On December 16, 2011, satellites including the Solar Dynamics Observatory (SDO) watched as the comet passed the Sun at a distance of just over 82,000 miles (130,000 km). Over the following days, observers in the Southern Hemisphere were astounded as the comet moved away from the Sun, becoming visible in the morning skies, and grew a long, featherlike tail. Astronauts on the International Space Station got a particularly good view.

SPACE STATION VIEW

This view from the International Space Station shows Comet Lovejoy’s tail extending upward from the horizon. The bands beneath are part of Earth’s atmosphere.

Sungrazer comets are thought to be fragments of a much larger comet that broke up long ago, possibly in the 12th century. The pieces have continued to orbit the Sun, disintegrating further as they do so. They are also known Kreutz sungrazers, because they were first studied in the 19th century by German astronomer Heinrich Kreutz. Comet Lovejoy has a calculated orbital period of 565 years.

TH E S OLA R S Y S TE M

SURVIVING THE SUN

ORBITAL PERIOD

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METEORS AND METEORITES

METEORS AND METEORITES POPULARLY KNOWN AS SHOOTING STARS, meteors

are linear trails of light-radiating material produced in Earth’s upper 170–75 Asteroids atmosphere by the impact of often small, dusty fragments of 212–19 Comets comets or asteroids called meteoroids. About 1 million visible Monthly sky guide 426–501 meteors are produced each day. If the meteor is not completely destroyed by the atmosphere, it will hit the ground and is then called a meteorite. If the meteorite is very large, a crater will be formed by the impact. 38–39 Gravity, motion, and orbits

METEOROIDS Most of the dusty meteoroids responsible for visual meteors come from the decaying surfaces of cometary nuclei. When a comet is close to the Sun, its surface becomes hot, and snow just below the surface is converted into gas. This gas escapes and breaks up the surface of the friable, dusty nucleus and blows small dust particles away from the comet. These dusty meteoroids have velocities that are slightly different from that of their parent comet. This causes them to have slightly different orbits, and as time passes they form a stream of particles all around the original orbit of the comet. This stream is fed by new meteoroids every time the parent comet swings past the Sun. The inner solar system is full of these streams. Dense streams are produced by large comets that get close to the Sun. Streams with relatively few meteoroids are formed by smaller and more distant comets. As the Earth orbits the Sun, it continually passes in and out of FIREBALL The brightest meteors of these streams, colliding with some of all are known as fireballs. the meteoroids that they contain. They have a magnitude of Names are given to some meteor at least –5, shining more showers that occur at fixed times of brightly than planets such year, such as the Leonids (right). as Venus and Jupiter.

TH E S O LA R S YS TEM

GIOVANNI SCHIAPARELLI Giovanni Schiaparelli (1835–1910) was an Italian astronomer who worked at the Brera Observatory in Milan and has two claims to fame. In 1866, he calculated the orbits of the Leonid and Perseid meteoroids and realized that they were similar to the orbits of comets Tempel–Tuttle and Swift–Tuttle, respectively. He concluded that cometary decay produced meteoroid streams. In the late 1870s, he went on to map Mars’s surface.

LEONID METEOR SHOWER

Leonid meteors are seen around November 17 every year and are so called because they appear to pour out of the constellation of Leo. Every 33 years, the shower strengthens into a veritable storm. The woodcut on the right was carved by the Swiss artist Karl Jauslin in 1888; it represents the maximum activity of the 1833 Leonids.

METEORITES

STONY

This is by far the most common type of meteorite, comprising 93.3 percent of all falls. They are subdivided into chondrites and achondrites.

Small extraterrestrial bodies that hit the Earth’s atmosphere are completely destroyed during the production of the associated meteor. If, however, the impacting body has a mass of between about 70 lb (30 kg) and 10,000 tons, only the surface layers are lost during atmospheric entry, and the atmosphere slows down the incoming body until it eventually reaches a “free-fall” velocity of just over 90 mph (150 km/h). The central remnant then hits the ground. The fraction of the incoming body that survives depends on its initial velocity and composition. Meteorites are referred to as “falls” if they are seen to enter and are then picked up just afterward. Those that are discovered some time later are called “finds.” Meteorites are classified as one of three compositional types. STONY-IRON

The rarest meteorites—just 1.3 percent of meteorite falls—are a mixture of stone and iron-nickel alloy, similar to the composition of the rocky planets.

IRON

Iron meteorites make up 5.4 percent of all falls. They are composed mainly of iron-nickel alloy (consisting of 5–10 percent nickel by weight) and small amounts of other minerals.

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METEOR TRAIL

Meteors are randomly occurring, narrow streaks of light that shoot across a few tens of degrees of the sky in just a few seconds. A typical meteor will be about 90 miles (150 km) away from the observer.

METEORITE IMPACTS

FINDING METEORITES

MOLDAVITE (GREEN GLASS)

The best way to find meteorites is to search exposed glacial ice-fields or sandy deserts free of other large rock. Ideal sites are the eroded blue-ice regions of Antarctica and the Nullarbor Plain in Australia. Since 1976, US, European, and Japanese expeditions have searched for meteorites in Antarctica, and thousands of individual specimens have been recovered. Many are from the same fall, due to the incoming body fragmenting as it passed through Earth’s atmosphere.

DISK-SHAPED TEKTITE

IMPACTITES

These half-inch, glassy bodies are formed when Earth’s rock melts or shatters due to the heat and pressure of an impact.

NOMAD ROVER IN ANTARCTICA

In January 2000, the US robot Nomad achieved a first by finding and identifying five meteorites lying on the ice in eastern Antarctica, using just sensors and artificial intelligence.

TH E S OL A R S Y S TE M

Earth’s atmosphere shields the surface from the vast majority of incoming extraterrestrial bodies. The typical impact velocity at the top of the atmosphere is about 45,000 mph (72,000 km/h), and the leading surface of the meteoroid quickly heats up and starts boiling as a result of hitting air molecules at this speed. Usually, the body is so small that it boils away completely. Parts of medium-sized bodies survive to fall as meteorites. A very large body, having a mass greater than about 100,000 tons, is, however, hardly affected by the atmosphere. It punches through the gas like a bullet through tissue paper, energetically slamming into Earth’s surface and gouging out a circular crater that is typically 20 times larger than its own size (see p.103). The enormous energy generated ensures that most of the impactor is vaporized in the process, and seismic shocks and blast waves are produced. The resulting huge earthquake will topple any trees for many miles around. The surrounding atmosphere reaches furnace temperatures, causing widespread fires. A tsunami will be produced if the impact is in IMPACT CRATER the ocean. An impact crater About 50,000 years ago, an iron meteorite hit this desert greater than 12 miles (20 km) region in Arizona. The resulting crater, called Meteor in diameter is produced on Crater, is 0.75 miles (1.2 km) wide and 550 ft (170 m) deep. Earth about once every Ejecta produced by the impact can be seen as hummocky 500,000 years. deposits lying beyond the crater rim.

EXPLORING SPACE

222

METEORS AND METEORITES

METEORITES Meteorites are mainly pieces of asteroids that have fallen to Earth from space, but a few very rare meteorites have come from the surface of Mars and the Moon. Some meteorites are made up of the primitive material that originally formed rocky planets. These give researchers a glimpse of the conditions at the dawn of the solar system. Others are fragments of bodies that have differentiated into metallic cores and rocky surfaces, providing an METEORITE CROSS-SECTION By shining polarized light through indirect opportunity to study the deep interior of a thin sections of chondrites (a type of rocky planet. Meteorites are named after the place stony meteorite), scientists can study where they landed. their crystalline structure.

NORTH AMERICA north

NORTH AMERICA southwest

Tagish Lake

Canyon Diablo

British Columbia, Canada

LOCATION

TYPE MASS

NORTH AMERICA south

Arizona

LOCATION

MASS

About 2.2 lb (1 kg)

LOCATION

TYPE

30 tons

DATE OF DISCOVERY

1891

FRAGMENT ENCASED IN ICE

Many pieces of this meteorite, ranging from minute fragments to chunks weighing about 1,100 lb (500 kg), have been found near Meteor Crater in Arizona. Much more is thought to be buried under one of the crater rims. If a Canyon Diablo meteorite is sawn in half and then one of the faces is polished and etched with acid, a characteristic surface pattern appears.

ACID-ETCHED, POLISHED CROSS-SECTION

EUROPE west

Stony 2 tons

DATE OF DISCOVERY

nodule of iron sulfide

1969

On February 8, 1969, a fireball was seen streaking across the sky above Mexico. It exploded, and a shower of stones fell over an area of about 60 square miles (150 square km). Two tons of material were speedily collected CHONDRULE

This thin, magnified section of an Allende meteorite shows one of many spherical, peasized chondrules that are locked in the stony matrix. Chondrules are droplets of silicate rock that have cooled extremely rapidly from a molten state.

EUROPE west

Glatton

AFRICA north

Ensisheim LOCATION

Cambridgeshire,

UK TYPE MASS

Nakhla LOCATION TYPE

Stony

MASS

27 oz (767 g)

DATE OF DISCOVERY

TH E S O LA R S YS TEM

MASS

2000

Over 500 fragments of this meteorite rained down onto the frozen surface of Tagish Lake on January 18, 2000. The meteorite was dark red and rich in carbon. Analysis showed that it was extremely primitive, containing many unaltered stellar dust grains that had been part of the cloud of material that formed the Sun and the planets.

Chihuahua,

Mexico

Iron

TYPE

Stony

DATE OF DISCOVERY

Allende

LUCKY FIND

Alsace, France

LOCATION

TYPE

280 lb (127 kg)

DATE OF DISCOVERY

MASS

1492

MEDIEVAL WOODCUT

This large stone is the oldest meteorite fall that can be positively dated. It was carefully preserved by being hung from the roof of the parish church of Ensisheim, Alsace. This veneration was due to the fall being regarded by the Holy Roman Emperor Maximilian as a favorable omen for the success of his war with France and his efforts to repel Turkish METEORITE FRAGMENT

This highly valuable 17.6-lb (8-kg) sample of the Ensisheim meteorite is kept at the Museum of Paris, France.

Alexandria,

Egypt

Stony

1991

On May 5, 1991, while planting out a bed of onions just before Sunday lunch, retired English civil servant Arthur Pettifor heard a loud whining noise. Noticing one of the conifers in his hedge waving around, he got up and looked in the bottom of the hedge. He spotted a small stone that was lukewarm to the touch. If Pettifor had not been gardening, the stony meteorite would never have been found.

and distributed among the scientific community. Allende was found to be a very rare type of primitive meteorite. Previously, only gram-sized amounts of this meteorite type were known. Since such large samples of Allende were available, destructive analysis was possible. The white calcium- and aluminum-rich crystals were separated from the surrounding rock. They were found to contain the decay products of radioactive aluminum-26, indicating that these crystals were formed in the outer shells of stars that exploded as supernovae and were subsequently incorporated into planetary material.

The woodcut at the top of this medieval manuscript shows the meteorite falling near Ensisheim after producing a brilliant fireball in the sky on November 16, 1492.

invasions. Initially, Ensisheim was thought to be a “thunderstone,” a rock ejected from a nearby volcano and subsequently struck by lightning. In the early 19th century, it was chemically analyzed and found to contain 2.3 percent nickel. This is very rare in rocks on Earth, and theories of an extraterrestrial origin started to proliferate.

Stony 88 lb (40 kg)

DATE OF DISCOVERY

1911

On June 28, 1911, about 40 stones landed near Alexandria, the largest weighing 4 lb (1.8 kg). Nakhla is a volcanic, lavalike rock that formed 1,200 million years ago. It is one of over 16 meteorites that have been blasted from the surface of Mars and, after many millions of years in space, fallen to Earth.

black, glassy fusion crust formed during fall MARTIAN METEORITE

METEORS AND METEORITES

223

AFRICA southwest

Hoba West LOCATION

Grootfontein,

Namibia TYPE MASS

Iron 66 tons

DATE OF DISCOVERY

1920

The largest meteorite to have been found on Earth, Hoba West measures 8.9 x 8.9 x 3 ft (2.7 x 2.7 x 0.9 m). It consists of 84 percent iron and 16 percent nickel. Hoba West has never been moved from where it landed. In the past, enterprising individuals tried to recover this valuable lump of “scrap” metal. To protect it from damage and sample-taking, the Namibian Government has declared it to be a national monument. Hoba West represents the maximum mass that the Earth’s

atmosphere can slow down to a free-fall velocity. If its parent meteoroid had been much bigger, or the trajectory of the fall steeper, the impact with the ground would have been much faster. This would have led to the destruction of most of the meteorite and the production of a crater in the Earth’s surface. Large lumps of surface iron, such as Hoba West, are hard to overlook.

RUSTING AWAY

The Hoba West meteorite weighed about 66 tons when it was discovered but it has started to rust away and today weighs less than 60 tons.

AFRICA south

Cold Bokkeveld Western Cape, South Africa

LOCATION

TYPE MASS

Stony About 8.8 lb (4 kg)

DATE OF DISCOVERY

1838

This meteorite is a perfect example of a stony chondrite, a class of primitive meteorite that makes up almost 90 percent of those found so far. They consist of silicate, metallic, and sulfide minerals and are thought to represent the material from which the Earth was formed. They contain tiny,

spherical chondrules cemented into a rocky matrix. These rocky droplets solidified extremely quickly from a starting temperature of at least 2,600°F (1,400°C). Chondrules contain a mixture of imperfect crystals and glass. Cold Bokkeveld is carbonaceous, which means that it contains compounds of carbon, hydrogen, oxygen, and nitrogen. These are the main constituents of living cells. Carbonaceous chondrites thus contain the building blocks of life. WATER FROM STONE

This tiny chondrule is surrounded by a waterrich matrix (shown in black). Cold Bokkeveld contains about 10 percent water by mass, which would be released if it was heated.

AUSTRALIA west

Mundrabilla Nullarbor Plain, Western Australia

LOCATION

TYPE MASS

years to solidify, and it offers a rare chance to investigate the formation of alloys at low gravity. A 100-lb (45-kg) core of one of the meteorites (below) is undergoing computer X-ray analysis by NASA.

About 18 tons 1911

Mundrabilla is on the Trans-Australian railroad line in a featureless desert. Three small irons were found there in 1911 and 1918. Renewed interest in 1966 led to the discovery of two meteorites weighing 5 and 11 tons. Mundrabilla took many millions of

ANTARCTICA

ALH 81005 Allan Hills, Antarctica

LOCATION

MASS

A team of scientists from Kings College, London, UK, poses on top of Hoba West in the 1920s. Standing second from the left is Dr. L.J. Spencer, who became Keeper of Minerals at the British Museum, London, in the 1930s.

Iron

DATE OF DISCOVERY

TYPE

LARGEST KNOWN METEORITE

Stony 1.1 oz (31.4 g) 1982

Moon by a meteorite impact in the last 20 million years. The main mineral is anorthite (calcium aluminum silicate), which is very rare in asteroids. The composition of these stony meteorites is very similar to that of the lunar-highland rocks brought back to Earth by the Apollo astronauts.

ALH 81005 is a lunar meteorite. anorthite About 36 have been discovered, a mere 0.08 percent of the present total. The cosmic-ray damage they have suffered indicates that they have been blasted from the surface of the MOON ROCK

This golf-ball-sized rock was found by the US Antarctic Search for Meteorites program in 1982. It was the first meteorite to be recognized as being of lunar origin.

TH E S OL A R S Y S TE M

DATE OF DISCOVERY

UNDER INVESTIGATION

TH E MI L KY WAY

224

“A broad and ample road, whose dust is gold, And pavement stars, as stars to thee appear Seen in the galaxy, that milky way Which nightly as a circling zone thou seest Powder’d with stars.” John Milton

THE SOLAR SYSTEM is part of a vast collection of stars, gas, and dust called the Milky Way galaxy. Galaxies can take various forms, but the Milky Way is a spiral. The Sun and its system of planets lie halfway from the center, on the edge of one of the spiral arms. For thousands of years, humans have pondered the significance of the pale white band that stretches through the sky. This Milky Way is the light from millions of stars that lie in the disk of the galaxy. Within the Milky Way lie stars at every stage of creation, from the immense clouds of interstellar material that contain the building material of stars, to the exotic stellar black holes, neutron stars, and white dwarfs that are the end points of a star’s life. Most of the Milky Way’s visible mass consists of stellar material, but about 90 percent of its total mass is made up of invisible “dark matter,” which is a mystery yet to be explained. GLOWING PATHWAY

From Earth, the Milky Way presents a glowing pathway of stars and gas vaulting across the night sky. The billions of stars that make up the Milky Way are arranged in a great spiral disk, and from our position, halfway from its center, we view the disk end-on.

THE MILKY WAY

226

THE MILKY WAY

THE MILKY WAY THE SUN IS ONE STAR

26 Galaxies 70–71 Star motion and patterns Star formation 238–39 Star clusters 288–89 Beyond the Milky Way 300–339

of around 100 billion that make up the Milky Way, a relatively large spiral galaxy (see p.302) that started to form around 13.5 billion years ago. From our position inside the Milky Way, it appears as a bright band of stars stretching across the night sky.

THE GEOGRAPHY OF THE MILKY WAY

BAND OF STARS

As we look out along the disk of the Milky Way from our position within, we see a bright band of thousands of stars that has captured humankind’s imagination throughout history.

solar system

globular cluster in spherical halo

central bulge

dark halo

galactic disk

At the very center of the Milky Way lies a black hole with a mass of about 3 million solar masses. This core or nucleus of the galaxy is surrounded by a bulge of stars that grows denser closer to the center. This forms an ellipsoid of about 15,000 by 6,000 light-years, the longest dimension lying along the plane of the Milky Way. Lying in the plane is the MILKY WAY GALAXY disk containing most of the Galaxy’s stellar materials. Young The Milky Way has a diameter of about 100,000 stars etch out a spiral pattern, and it is thought that they and a thickness radiate out from a bar. Surrounding the bulge and disk is a light-years of about 2,000 light-years. spherical halo in which lie some 200 globular clusters, and The Sun lies about 25,000 this in turn may be surrounded by a dark halo, the corona. light-years from the center. Sagittarius Arm

Scutum Arm

Orion Arm

3KPC Arm

Centaurus Arm

Norma Arm

TH E M I LKY WAY

the solar system

distance in thousands of light-years from center 180°

Carina Arm

THE MILKY WAY

227

GALACTIC CENTRE

THE SPIRAL ARMS Seen “face-on,” the Milky Way would look like a huge catherine wheel, with the majority of its light coming from the arms spiraling out from the central bulge. In fact, the material in the spiral arms is generally only slightly denser than the matter in the rest of the disk. SATURN CENTAURUS ARM It is only because the stars that lie within them are younger, and therefore brighter, that the pattern in spiral galaxies shows up. Two mechanisms are thought to create the Milky Way’s spiral structure. Density waves, probably caused by gravitational attraction from other galaxies, ripple out through the disk, creating waves of slightly denser material and triggering star formation (see pp.238–39). By the time the stars have become bright enough to etch out the spiral pattern, the density waves have moved on through the disk, starting more episodes of star formation and leaving the young NORMA ARM stars to age and fade. High-mass stars eventually explode as supernovae, sending SPINNING GALAXY out blast waves that The galaxy rotates differentially—the closer also pass through the objects are to the center, the less time they take star-making material, to complete an orbit. The Sun travels around the galactic center at about 500,000 mph (800,000 km/h), triggering further star formation. taking around 225 million years to make one orbit. NEAR 3KPE ARM

SAGITTARIUS ARM

FAR 3KPE ARM

PERSEUS ARM

OUTER ARM

MYTHS AND STORIES

HEAVENLY MILK ORION SPUR THE SOLAR SYSTEM

HALO OF GAMMA RAYS

A vast halo of gamma rays surrounds the Milky Way. The halo may be thousands of light-years thick and might help to define the edges of the Milky Way.

There are many myths involving the formation of the Milky Way. In Greek mythology, Hercules was the illegitimate son of Zeus and a mortal woman, Alcmene. It was said that when Zeus’s wife, while suckling Hercules, heard he was the son of Alcmene, she MYTH IN ART pulled her breast The Origin of the Milky away and her Way (c. 1575) by Jacopo milk flowed Tintoretto was inspired by the Greek myth. among the stars.

STELLAR POPULATIONS Stars are broadly classified into two groups, called populations, based on age and chemical content. Population I consists of the youngest stars, which tend to be richer in heavy elements. These elements are primarily produced by stars, and Population I stars are created from materials shed by existing stars. In the Milky Way, the majority of Population I stars lie in the galactic disk, where there is an abundance of star-making material. Population II stars are older, metal-poor stars, existing primarily in the halo, but also in the bulge. Most are found within globular clusters, where all star-making materials have been used up and no new star formation is taking place.

STAR MOTION

The stars in the bulge have the highest orbital rates. They can travel thousands of light-years above and below the plane of the Milky Way. Within the disk, stars stay mainly in the plane of the galaxy as they orbit the galactic center. Stars in the halo plunge through the disk, reaching distances many thousands of lightyears above and below it. bulge-star orbit

MAPPING THE MILKY WAY

halo-star orbit

disk-star orbit

TH E MI L KY WAY

The Milky Way’s structure is defined by its major arms, each named after the constellation in which it is most prominent – the brightest arm is that in Sagittarius, beyond which lies the galactic nucleus. The solar system lies near the inner edge of the Orion Arm. All the arms lie in a plane defined by the galactic disk. The nucleus forms a bulge at its center, and globular clusters orbit above and below it in the halo region.

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THE MILKY WAY

THE INTERSTELLAR MEDIUM

TH E M I LKY WAY

The interstellar medium, permeating the space between the stars, consists mainly of hydrogen in various states, together with dust grains. It constitutes about ten percent of the mass of the Milky Way and is concentrated in the galactic disk. It is not distributed uniformly: there are clouds of denser material, where star formation takes place, and regions where material has been shed by stars, interspersed with areas of very low density. Within the interstellar medium there is a wide range of temperatures. In the cooler regions, at around –440°F (–260°C), hydrogen exists as clouds of molecules. These cold molecular clouds contain molecules other than hydrogen, and star formation occurs where such clouds collapse. There are also clouds of neutral hydrogen (HI regions) with temperatures ranging from –280°F (–170°C) to 1,340°F (730°C), and areas of ionized hydrogen heated by stars (HII regions) with temperatures around 18,000°F (10,000°C). Dust grains contribute about one percent of the galactic mass and are found throughout the medium. They are mostly small, solid grains, 0.01 to 0.1 micrometers in diameter, consisting of carbon, silicates (compounds of silicon and oxygen) or iron, with mantles of water and ammonia ice or, in the cooler clouds, possibly solid carbon dioxide.

NONUNIFORM MEDIUM

As this image of the Cygnus Loop supernova remnant (see p.269) shows, material in the interstellar medium is very uneven. The blast wave from the supernova explosion is still expanding through the interstellar matter. Where it hits denser areas and slows down, atoms in the medium become excited and emit optical and ultraviolet light.

INVISIBLE COSMIC RAYS

STARS

DARK NEBULAE

MAGNETIC FIELDS

Cosmic rays travel throughout the Milky Way. These are highly energetic particles that spiral along magnetic field lines. Cosmic rays are primarily ions and electrons and are an important part of the interstellar medium, producing a pressure comparable to that of the interstellar gas.

Stars are an important factor in the composition of the interstellar medium since they enrich the medium with heavy, metallic elements. A supernova explosion, the death of a massive star (see p.266), is the only mechanism that produces elements heavier than iron.

Dark nebulae are cool clouds composed of dust and the molecular form of hydrogen. They are only observed optically when silhouetted against a brighter background as they absorb light and reradiate the energy in infrared wavelengths. Stars are formed when dark nebulae collapse.

Galactic magnetic fields are weak fields that appear to lie in the plane of the Milky Way, increasing in strength toward the center. They are aligned with the spiral arms, but are distorted locally by events such as the collapse of molecular clouds and supernovae.

BETWEEN THE STARS

DUST CLOUDS

REFLECTION NEBULAE

EMISSION NEBULAE

Contrary to early popular belief, the space between stars is not empty. The interstellar medium is fundamental in the process of star formation and galaxy evolution. Temperature defines the material’s appearance and the processes occurring within it.

Young stars are often surrounded by massive disks of dust. These disks are believed to be the material from which solar systems are formed. There are often high levels of dust around stars in the later stages of their lives as they lose material to the interstellar medium.

Material surrounding young stars contains dust grains that scatter starlight. In these nebulae, the density of the dust is sufficient to produce a noticeable optical effect. The nebulae appear blue because the shorter-wavelength, bluer light is scattered more efficiently.

When the interstellar medium is heated by stars, the hydrogen is ionized, producing a so-called HII region. The electrons freed by the ionization process are continually absorbed and reemitted, producing the red coloring observed in emission nebulae.

THE MILKY WAY

OUR LOCAL NEIGHBORHOOD

Bug Nebula Dumbbell Nebula

Gum Nebula

Antares

LOOP I

Coalsack Canopus

LOOP III

Deneb

SUN

Hyades

Betelgeuse

LOOP II

Pleiades Lacerta OB1

Taurus Dark Cloud

Red Rectangle Nebula Rigel Barnard’s Loop

Vela Supernova Remnant

Orion Nebula

The Sun lies in one of the less-dense regions of the Milky Way’s Orion Arm. It sits in a “bubble” of hot, ionized hydrogen gas bounded by a wall of colder and denser neutral hydrogen gas. The Local Bubble is part of a tubelike chimney that extends through the disk into the galactic halo. The largest local coherent structure, detected by radioand X-rays, is known as Loop I. This is believed to be part of the Local Bubble impacting into a molecular cloud known as the Aquila Rift. Two other expanding bubbles, Loops II and III, lie nearby. The Sun is traveling through material flowing out from the young stars known as the Scorpius–Centaurus Association, toward the Local Interstellar Cloud, a mass of dense interstellar gas.

Horsehead Nebula

Epsilon Aurigae

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to the Galactic Center

Scorpius–Centaurus Association

Gum Nebula

Vela Supernova Remnant

AE Aurigae

Camelopardalis OB1 Cone Nebula

LOCAL BUBBLE

Monoceros R2

The Sun moves within the boundaries of the Local Bubble (shown in black). It is passing through strong stellar winds (shown in blue) thrown out by the Scorpius–Centaurus Association of young stars. High-density molecular clouds are highlighted in red.

Aquila Rift

REGIONAL MAP

This schematic representation of the solar system’s local neighborhood maps out a section of the Milky Way’s Orion Arm about 5,000 light-years across. The Sun is located just above center. Hydrogen gas clouds are marked in brown, molecular clouds in red, and interstellar bubbles are colored green. Nebulae are shown in pink, while star clusters and giant stars are picked out in white.

direction of Sun’s movement

Sun

THE GALACTIC CENTER

Local Bubble

Orion Shelf

Dense layers of dust and gas obscure the center of the Milky Way Sagittarius A from us in optical wavelengths. However, the brightest radio East Radio source in the sky is located toward the Galactic Center in the Lobe constellation of Sagittarius. This source, known as Sagittarius A Arc consists of two parts. Sagittarius A East is believed to be a bubble of ionized gas, possibly a supernova remnant. Sagittarius A* Sagittarius A West is a cloud of hot gas, and embedded Sagittarius A within it is a very strong and compact radio source, called West Sagittarius A* (Sgr A*). Sgr A* appears to have no orbital Molecular Ring 1,000 light-years motion and therefore probably lies at the very center of across the Milky Way. It has a radius of less than 1.4 billion miles (2.2 billion km)—smaller than that of Saturn’s orbit—and orbital motions of the gas clouds around it GALACTIC CENTER Surrounding Sagittarius A, the Radio Lobe is a region of indicate that it surrounds a supermassive black hole of magnetized gas including an arc of twisted gas filaments. about 3 million solar masses. Centered on Sgr A* is a Farther out, the expanding Molecular Ring consists of a three-pronged mini-spiral of hot gas, about 10 lightseries of huge molecular clouds (red), and an association of years in diameter, and surrounding this is a disk of hydrogen clouds (brown) and nebulae (pink). The two smaller gas disks around Sagittarius A cannot be seen at this scale. cooler gas and dust called the Circumnuclear Disk.

RADIO MAPS

Radio maps of Sagittarius A show a spiral pattern of hot, ionized gas that appears to be falling into the very center of the Milky Way. Situated at the middle of the maps is the point source Sagittarius A*, thought to be a supermassive black hole at the very heart of the Milky Way.

THE EDGES OF THE MILKY WAY

J.C. KAPTEYN

GLOBULAR CLUSTER

Like bees around a honey pot, the stars of a globular cluster swarm in a compact sphere. Containing up to a million (mostly Population II) stars, most of these clusters are found in the Milky Way’s halo.

Surrounding the disk and central bulge of the Milky Way is the spherical halo, stretching out to a diameter of more than 100,000 lightyears. Compared to the density of the disk and the bulge, the density of the halo is very low, and it decreases as it extends away from the disk. Throughout the halo are about 200 globular clusters (see pp.288–89), spherical concentrations of older, Population II stars (see p.227). Individual Population II stars also exist in the halo. These halo stars orbit the galactic center in paths that take them far from the galactic disk, and because they do not follow the motion of the majority of the stars in the disk, their relative motion to the Sun is high. For this reason, they are sometimes called high-velocity stars. Calculations of the mass of the Milky Way suggest that 90 percent consists of mysterious dark matter (see p.27). Some of this may be composed of objects with low luminosities, such as brown dwarfs and black holes, but most is believed to be composed of exotic particles, the nature of which have yet to be discovered. The halo extends into the corona, which reaches out to encompass the Magellanic Clouds (see pp.310–311), the Milky Way’s nearby neighbors in space.

T HE M I L KY WAY

Dutch astronomer Jacobus Cornelius Kapteyn (1851–1922) was fascinated by the structure of the Milky Way. Studying at the University of Groningen, he used photography to plot star densities. He arrived at a lens-shaped galaxy with the Sun near its center. Although his positioning of the Sun was incorrect, many subsequent studies of the structure of the Milky Way

Orion Association

THE GALACTIC CENTER

NASA’s three Great Observatories—Chandra, Hubble, and Spitzer—gazed into the center of our Galaxy to create this composite image. Hubble observations (yellow) trace nebulae where stars are being born. Red represents Spitzer’s infrared observations, while blue and violet represent the X-ray observations of Chandra. The exact center of the Galaxy lies within the white region near the center.

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STARS

STARS STARS ARE MASSIVE

gaseous bodies that generate energy by nuclear reactions and shine because of this energy source. The mass of a star determines its properties—such as luminosity, temperature, and size—and its evolution over time. Throughout its life, a star achieves equilibrium by balancing its internal pressure against gravity.

25 Stars and brown dwarfs 55 The first stars 104–107 The Sun The life cycles of stars 234–37 Star formation 238–39

radiation in form of light

WHAT IS A STAR?

internal pressure

A collapsing cloud of interstellar matter becomes a star when the pressure and temperature at its center become so high that nuclear reactions start (see pp.238–39). A star converts the hydrogen in its core into helium, releasing energy that escapes through the star’s body and radiates out into space. The pressure of the escaping energy would blow the star apart if it were not for the force of gravity acting in opposition. When these forces are in equilibrium, the star is stable, but a shift in the balance will change the star’s state. Stars fall within a relatively narrow mass range, since nuclear reactions cannot be sustained below about 0.08 solar masses, and in excess of about 100 solar masses stars become unstable. A star’s life cycle, as well as its potential age, is directly linked to its mass. High-mass stars burn their fuel at higher rates and live much shorter lives than low-mass stars.

force of gravity

PRESSURE BALANCE

The state and behavior of any star, at any stage in its evolution, are dictated by the balance between its internal pressure and its gravitational force.

SURFACE TEMPERATURE (THOUSANDS OF DEGREES CELSIUS) 30

20

10

9

8

7

6

5

4

3 -10

Canopus

Alnilam

Mu Cephei

SUPERGIANTS

Deneb

Rigel 100,000

Betelgeuse

Mirfak Polaris

Antares

Alnitak Spica Achernar

1,000 Alnath Regulus

100

-0 Altair

Gacrux Procyon A

Aldebaran Arcturus Pollux

Fomalhaut

MAIN SEQUENCE

1

Alpha Centauri B

+5

Alpha Centauri A Sun 0.1

Sirius B

61 Cygni A 61 Cygni B

Tau Ceti

40 Eridani B ZZ Ceti

0.01

+10

Procyon B

0.001 Barnard’s Star +15

0.0001

Proxima Centauri

WHITE DWARFS 0.00001 O

B

A

F SPECTRAL TYPE

G

K

M

ABSOLUTE MAGNITUDE

LUMINOSITY (SUN = 1)

Dubhe

Castor

Sirius

10

RED GIANTS

Alphard

Alioth

Vega

TH E M I LKY WAY

THE H–R DIAGRAM

-5

10,000

Named after the Danish and American astronomers Ejnar Hertzsprung and Henry Russell, the Hertzsprung–Russell (H–R) diagram graphically illustrates the relationship between the luminosity, surface temperature, and radius of stars. The astronomers’ independent studies had revealed that a star’s color and spectral type are indications of its temperature. When the temperature of stars was plotted against their luminosity, it was noticed that stars did not fall randomly, but tended to be grouped. Most stars lie on the main sequence, a curved diagonal band stretching across the diagram. Star radius increases diagonally from bottom left to top right. Protostars evolve onto the main sequence as they reduce in radius and increase in temperature. On the main sequence, stars remain at their most stable before evolving into red giants or supergiants, moving to the right of the diagram as IMPORTANT DIAGRAM The H–R diagram is the most important their radius increases diagram in astronomy. It illustrates and their temperature the state of a star throughout its life. falls. White dwarfs Distinct groupings represent different are at the bottom left stellar stages, and few stars are with small radii and found outside these groups, since high temperatures. they spend little time migrating.

STARS

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STELLAR SPECTRAL TYPES TYPE

PROMINENT SPECTRAL LINES +

2+

2+

2+

3+

COLOR

AVERAGE TEMPERATURE

EXAMPLE

O B A

He , He, H, O , N , C , Si He, H, C+, O+, N+, Fe2+, Mg2+ H, ionized metals

Blue Bluish white White

80,000°F (45,000°C) 55,000°F (30,000°C) 22,000°F (12,000°C)

Gamma Velorum (p.253) Rigel (p.281) Sirius (p.252)

F G

H, Ca+, Ti+, Fe+ Ca+, Fe, Ti, Mg, H, some molecular bands

Yellowish white Yellow

14,000°F (8,000°C) 12,000°F (6,500°C)

Procyon (p.284) The Sun (pp.104–107)

K M

Ca+, H, molecular bands TiO, Ca, molecular bands

Orange Red

9,000°F (5,000°C) 6,500°F (3,500°C)

Aldebaran (p.256) Betelgeuse (p.256)

STELLAR CLASSIFICATION Stars are classified by group, according to the characteristics of their spectra. If the light from a star is split into a spectrum, dark absorption and bright emission lines are seen (see p.35). The positions of these lines indicate what elements exist in the photosphere of the star, and the strengths of the lines give an indication of its temperature. The classification system has seven main spectral types, running from the hottest O stars to the coolest M stars. Each spectral type is further divided into 10 subclasses denoted by a number from 0 to 9. Stars are also divided into luminosity classes, denoted by a Roman numeral, which indicates the type of star and its position on the H–R diagram. For example, class V is for mainsequence stars and class II for bright giants, while dim dwarfs are class VI. In addition to the main spectral types, there CONTRASTING SUPERGIANTS are classes for stars that show Both Betelgeuse (above) and Rigel (left) are supergiants, but they are unusual properties, such as the at opposite ends of the stellar carbon stars (C class). A small spectrum. Betelgeuse (see p.256) letter after the spectral class can is a cool, red star, in its later also indicate a special property— stages, while Rigel is a hot, blue, for example, “v” means variable. relatively young star (see p.281).

MAIN-SEQUENCE STAR

Shown here in a false-color image, the Sun is a yellowish main-sequence star with a surface temperature of 9,900°F (5,500°C) and spectral type G2, class V.

LUMINOSITY

DENEB AND VEGA

Although Deneb (bottom) and its neighbor Vega (top) are similar in apparent brightness, Deneb is about 300 times more distant. If Deneb were moved to Vega’s distance of only 25 lightyears from Earth, it would appear to be as bright as a crescent moon.

CECILIA PAYNEGAPOSCHKIN Born and educated in England, Cecilia Helena Payne (1900–79) married fellow astronomer Sergei Gaposchkin. Initially studying at Cambridge University, England, Payne-Gaposchkin was one of the first astronomy graduates to enter Harvard College Observatory. She studied the spectra of stars and suggested in her doctoral thesis that the different strengths of absorption lines in stellar spectra were a result of temperature differences, rather than chemical content. She also suggested that hydrogen was the most abundant element in stars. Her ideas were initially dismissed, but finally accepted in 1929.

HARVARD PROFESSOR

Cecilia PayneGaposchkin was the first woman to become a full professor at Harvard.

TH E MI L KY WAY

The luminosity of a star is its brightness, defined as the total energy it radiates per second. It can be calculated over all wavelengths—the bolometric luminosity—or at particular wavelengths. Measuring the brightness of a star as it appears in the night sky gives its apparent magnitude, but this does not take account of its distance from Earth. Stars that are located at vastly different distances from Earth can have the same apparent magnitudes if the farther star is sufficiently bright (see p.71). Once a star’s distance is known, its absolute magnitude can be determined. This is its intrinsic brightness, and from this its luminosity can be determined. Stellar luminosities are generally expressed as factors of the Sun’s luminosity. There is a very large range of stellar luminosities, from less than one ten-thousandth to about a million times that of the Sun. If stars are of the same chemical composition, their luminosities are dependent on their mass. Apart from highly evolved stars, they generally obey a consistent mass–luminosity relation, which means that if a star’s luminosity is known, its mass can be determined.

234

THE LIFE CYCLES OF STARS

THE LIFE CYCLES OF STARS STARS FORM WHEN

232–33 Stars Star formation 238–39 Main-sequence stars 250–51 Old stars 254–55 Stellar endpoints 266–67 Extra-solar planets 296–99

clouds of interstellar gas collapse under the influence of gravity (see pp.238–39). During their lifetimes, stars pass through a series of stages, with the sequence and timing depending crucially on the mass of the star. As a star passes through these stages, different elements are created, again depending on the star’s mass. When stars have completed their development, they shed their material back into the interstellar medium, enriching the matter from which future generations of stars will form. clouds begin to collapse

The environs of the nebula NGC 3603 display most stellar life stages, from “pregnant” dark nebulae and pillars of hydrogen, to a cluster of young stars, and a red star nearing its end. shroud of gas and dust

protostar

DENSE CLOUDS START TO COLLAPSE

PROTOSTARS BEGIN TO FORM

PRESSURE AND TEMPERATURE RISE

Stars form from cold interstellar clouds. The colder the cloud, the less resistant it is to gravitational collapse. Clouds are formed mostly of hydrogen. At low temperatures, hydrogen atoms combine to form molecules (molecular hydrogen).

If the cloud is over a certain mass, and it experiences a gravitational tug, it will begin to collapse. As it does, it will fragment into smaller parts of differing size and mass. These fragmented cloud sections become protostars.

The protostar continues to collapse, and the central temperature and pressure build up. The temperature and pressure levels will depend on the initial mass of the fragment—the higher the mass, the higher the temperature and pressure.

star

star sheds material during the course of its life

nuclear reactions in star produce heavier elements

TH E M I LKY WAY

LIFE STAGES

mass loss stars forming clouds condense to form stars molecular cloud

gas and dust particles shed by stars join with interstellar material in gigantic molecular clouds

STAR-MAKING RECIPE The basic ingredients of stars are found in cold clouds made mostly of hydrogen molecules. The early stages of star formation are initiated by gravity, which can be exerted by the tug of a passing object, a supernova shock wave, or the compression of one of the Milky Way’s density waves. If the cloud has sufficient mass, it will collapse into a protostar, which contracts until nuclear reactions start in its core. At this point a star is born. During its lifetime, a star will convert hydrogen to helium and a series of heavier materials, depending on its mass. These materials are gradually lost to the interstellar medium, ONGOING CYCLE until the star has used up most of Stars form from material shed its fuel and begins to collapse. For by previous generations of a high-mass star, this will result in stars, and the death of a supernova that scatters much of massive stars can trigger the remaining material into space. the birth of others.

BROWN DWARF

In protostars less than 0.08 solar masses, the pressure and temperature at the core do not get high enough for nuclear reactions to begin. These protostars become brown dwarfs.

STELLAR EVOLUTION

strong stellar winds

collapse, after burning fuel in their atmospheres.

red supergiant planetary nebula

red giant

evolutionary path of lowermass star high-mass blue giant

M

A

low-mass, Sun-like star

IN S

shrinking lowmass star becomes white dwarf

E

Q

U

E

N

C

E

white dwarf

LUMINOSITY

If they are of a sufficient mass, new stars will go onto the main sequence, where they will remain for most of their lives. When the hydrogen fuel in their cores is exhausted, they will evolve off the main sequence to become red giants or supergiants. Mass dictates what path stars will follow in their maturity. When a star expands as it burns fuel in its atmosphere or collapses after using up its fuel, it crosses a region to the right of the main sequence on the Hertzsprung–Russell (H–R) diagram (see p.232) known as an instability strip. The more massive the star, the more times it will expand and contract. High-mass stars explode as supernovae in the supergiant region of the H–R diagram, while lowmass stars cross back over the main-sequence band as they collapse to form white dwarfs. Being small and hot, white dwarfs appear in the bottom left of the H–R diagram. As they cool they move to the right, eventually cooling to STELLAR MATURITY become black dwarfs. Neutron stars and black The paths of mature stars on their journey toward death holes do not appear can be traced on the H–R on the H–R diagram Stars expand off to because they do not fit diagram. the right as they get larger the mass–luminosity and cooler to become red relationship that giants or supergiants. They travel back leftward as they it represents.

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supernova

evolutionary path of high-mass star

red dwarf

SURFACE TEMPERATURE

STELLAR ADOLESCENCE

STAR REACHES MAIN SEQUENCE

The gas that contracts to make a protostar starts to rotate slowly and speeds up as it is pulled inward, creating a disk of stellar material. Before joining the main sequence, the protostar exhibits unstable behavior such as rapid rotation and strong winds.

For protostars with a mass of more than about 0.08 solar masses, the pressure and temperature within become high enough for nuclear reactions to start. The pressure balances gravity, and the protostar becomes a star.

circumstellar disk

FORMATION OF A PLANETARY SYSTEM Most young stars, unless they are in a close binary system, are surrounded by the remnants of the material from which they have formed. Rotation and stellar winds often shape the material into a flattened disk around the equatorial radius. Initially, the disk of material is hot, but as the star settles down onto the main sequence, it begins to cool. As it cools, different elements condense out, depending on the disk’s temperature. Elements can exist in different states throughout the disk. Moving out from the star, temperatures fall, so water, for example, will exist as ice far away from the star and steam close to the star. Tiny condensing particles gradually stick together and grow larger. The ones that grow fastest will gravitationally attract others, becoming larger still, though in the dynamic early stages they may be broken back into pieces by collisions with other growing particles. Eventually, as the disk cools down, it becomes a calmer environment, and some particles will grow large enough to be classed as planetesimals—embryonic planets. Remnants of the original disk that do not form planets become asteroids or comets, depending on their distance from the parent star. Atmospheres are formed by gas attracted from the circumstellar disk, from gases erupting from the planets, or from bombarding comets.

FORMATION OF ORBITING PLANETS

Once a star is on the main sequence and stable, any disk of remaining material will start to cool. As it cools, elements condense out and begin to stick together. The larger clumps attract the smaller ones, until conglomerations are planet-sized.

CIRCUMSTELLAR DISK

Within the circumstellar disk of AB Aurigae, knots of material may be in the early stages of planet formation. This swirling disk of stellar material is about 30 times the size of the solar system.

236

THE LIFE CYCLES OF STARS

FROM MATURITY TO OLD AGE When a star has finished burning hydrogen in its core, it will start burning its outer layers in a series of concentric shells. The star will expand as the source of heat moves outward and its outer layers cool. Stars with very low mass will eventually fade and cool; Sun-like stars will evolve into red giants; and highmass stars will become supergiants. Once a star has used up all its available nuclear fuel, it will deflate, because there is no longer any power source to replace the energy lost from its surface. As it collapses, if it has enough mass, its helium core starts to burn and change into carbon. Once the fuel in its core is used up again, helium-shell burning begins in the star’s atmosphere and the star expands. In very massive stars, this process is repeated until iron is produced. When a Sun-like star has used up all of its fuel, it will lose its outer atmosphere in a spectacular planetary nebula and collapse to become a white dwarf. A high-mass star will explode as a supernova and leave behind a neutron star or black hole.

star expands as hydrogen-shell burning occurs

star starts to collapse as hydrogen is used up

LOW-MASS STAR

Once a star with a mass less than half that of the Sun has used up the hydrogen in its core, it will convert the hydrogen in its atmosphere to helium and collapse, just as in higher-mass stars. However, low-mass stars do not have enough mass for the temperature and pressure at its core to get high enough for helium burning to occur. These stars will just gradually fade as they cool.

SUN-LIKE STAR STAR NOW ON THE MAIN SEQUENCE

Stars spend the greatest proportion of their lives on the main sequence. The more massive the star, the shorter the period of time it will spend on the main sequence, since larger stars burn their fuel at a faster rate than smaller ones.

When a Sun-like star exhausts the hydrogen in its core, hydrogenshell burning begins and it becomes a red giant, often losing its outer layers to produce a planetary nebula. It eventually collapses, and the temperature and pressure at its core initiate helium-core burning. The star again expands as helium-shell burning occurs, before finally collapsing to become a white dwarf that gradually fades to black.

star becomes a red giant as hydrogenshell burning starts

HIGH-MASS STAR MOSTLY MAIN SEQUENCE STARS

About 90 percent of the visible stars in a typical view of the night sky are on the main sequence. This corresponds with the fact that most stars spend 90 percent of their life on the main sequence.

The higher the mass of the star, the more times it will expand and contract—its mass dictates the temperature of the core each time it contracts. Different elements are produced at each stage. If the star is massive enough, an iron core is formed, but elements heavier than iron cannot be formed within stellar cores. They are formed in supernova explosions that leave behind neutron stars or black holes.

supergiant star produces heavier elements through nuclear reactions

THE LIFE CYCLES OF STARS

237

OLD RED GIANTS

Red giants and supergiants appear very distinctive in the sky since they are noticeably red. As they are so large, they are also quite luminous, which makes them easy to detect.

star continues to collapse as no helium burning occurs

only gas pressure counterbalances gravity

small, dim star, gradually fades

star eventually becomes a small, dim black dwarf

red giant

star collapses after burning its helium shell to become a white dwarf

white dwarf will fade over time to become a black dwarf

planetary nebula

neutron stars are extremely compact and dense, composed mainly of neutrons

red giant’s outer layers start to form planetary nebula

black holes are objects so dense that even light cannot escape

After undergoing its red giant or supergiant stage, the stellar remnant will collapse. If its mass is over 1.4 solar masses, it will collapse to become a neutron star. If the remnant is above about 3 solar masses, it will collapse to become a black hole.

TH E MI L KY WAY

COLLAPSING STAR star explodes as a supernova, producing elements heavier than iron

238

STAR FORMATION

STAR FORMATION STARS ARE FORMED

by the gravitational collapse of cool, dense interstellar clouds. These clouds are composed mainly 55 The first stars of molecular hydrogen (see p.228). A cloud has to be of a 228 The interstellar medium certain mass for gravitational collapse to occur, and a trigger 232–33 Stars is needed for the collapse to start, since the clouds are held 234–37 The life cycles of stars up by their own internal pressure. Larger clouds fragment as Star clusters 288–89 they collapse, forming sibling protostars that initially lie close together—some so close they are gravitationally bound. The material heats up as it collapses until, in some clouds, the temperature and pressure at their centers become so great that nuclear fusion begins and a star is born. 24–27 Celestial objects

STAR-FORMING REGION

In the nebula RCW 120, in the southern Milky Way, an expanding bubble of ionized gas is causing the surrounding material to collapse into dense clumps, in which new stars will be born.

STELLAR NURSERIES As well as being among the most beautiful objects in the universe, star-forming nebulae contain a combination of raw materials that makes star birth possible. These clouds of hydrogen molecules, helium, and dust can be massive systems, hundreds of light-years across or smaller individual clouds, known as Bok globules. Although they may lie undisturbed for millions of years, disturbances can trigger these nebulae to collapse and fragment into smaller clouds from which stars are formed. Remnants from the star-forming nebulae will surround the stars, and the stellar winds produced by the new stars can, in turn, cause these remnants to collapse. If the clouds are part of a larger complex, this can become a great stellar nursery. Massive stars have relatively short lives, and they can be born, live, and die as a supernova while their less-massive siblings are still forming. The shock wave from the supernova FORMATION IN ACTION may plow through nearby interstellar Within the nebula NGC 2467 lie stars matter, triggering yet more star birth. at various stages of formation. At the

TH E M I LKY WAY

lower left lies a very young star that is breaking free of its surrounding birth cocoon of gas. On the far right, a wall of bright gas glows as it is evaporated by the energy of many newly formed hot stars. Dark lanes of dust at the center hide parts of the nebula that are probably forming new stars.

BOK GLOBULE

Small, cool clouds of dust and gas, known as Bok globules, are the origins of some of the Milky Way’s lower-mass stars. Bok globule

stellar EGGS

STELLAR EGGS

Within the evaporating gaseous globules (EGGS) of the Eagle Nebula, interstellar material is collapsing to form stars.

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TRIGGERS TO STAR FORMATION Clouds of interstellar material need a trigger to start them collapsing, since they are held up by their own pressure and that of internal magnetic fields. Such a trigger might be as simple as the gravitational tug from a passing star, or it might be a shock wave caused by the blast from a supernova or the collision of two or more galaxies. In spiral galaxies such as the Milky Way, density waves move through the dust and gas in the galactic disk (see p.227). As the waves pass, they temporarily increase the local density of interstellar material, causing it to collapse. Once the waves have passed, their shape can be picked out by the trails of bright young stars.

GALACTIC COLLISIONS

A ring of stars is created when two galaxies collide. Here, shock waves have rippled out, triggering star formation in the interstellar material. FROM OLD TO NEW

Shock waves and material from a supernova blast spread out through the interstellar medium, triggering new star formation.

STAR CLUSTERS When they have formed from the fragmentation of a single collapsing molecular cloud, young stars are often clustered together. Many stars are formed so close to their neighbors that they are gravitationally bound, and some are even close enough to transfer material. It is unusual for a star not to be in a multiple system such as a binary pair (see pp.274–75), and in this respect, the Sun is uncommon. Stars within a cluster usually have a similar chemical composition, although, since successive generations of stars may be produced by a single nebula, clusters may contain stars of different ages (see pp.288–89). Remnants of dust and gas from the initial cloud will linger, and the dust grains often reflect the starlight, predominantly in the shorter blue wavelengths. Thus, young star clusters are often surrounded by distinctive blue reflection nebulae. Young stars are hot VIOLENT STAR FORMATION and bright, and any nearby interstellar material will Young star clusters (blue) and starforming regions (pink) abound in NGC be heated by new stars’ heat, producing red emission 1427A. As the galaxy’s gas collides nebulae. Stars’ individual motions will eventually with the intergalactic medium through cause a young star cluster to dissipate, though which the galaxy is traveling, the multiple stellar systems may remain gravitationally resulting pressure triggers violent but stunning star-cluster formation. bound and may move through a galaxy together.

star-forming region

young star clusters

TOWARD THE MAIN SEQUENCE As collapsing fragments of nebulae continue to shrink, their matter coalesces and contracts to form protostars. These stellar fledglings release a great deal of energy as they continue to collapse under their own gravity. However, they are not easily seen because they are generally surrounded by the remnants of the cloud from which they formed. The heat and pressure generated within protostars acts against the gravity of their mass, opposing the collapse. Eventually, matter at the centers of the protostars gets so hot and dense that nuclear fusion starts and a star is born. At this stage, stars are very J.L.E. DREYER unstable. They lose mass by expelling strong stellar winds, Danish–Irish astronomer John which are often directed in two Louis Emil Dreyer (1852–1926) opposing jets channeled by a compiled the New General disk of dust and gas that forms Catalog of Nebulae and Clusters around their equators. Gradually, of Stars, from which nebulae and galaxies get their NGC number. At the balance between gravity and the time of compilation, it was not pressure begins to equalize and known if all the nebulous objects the stars settle down on to the were within the Milky Way. Dreyer main sequence (see pp.234–37). studied the proper

polar gas jets

accretion disk

ADOLESCENT STAR

T Tauri (above) is the prototype of a type of adolescent star that is still undergoing gravitational contractions. These stars have extensive accretion discs and violent stellar winds coming from their poles (left).

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motions of many and concluded the “spiral nebulae,” now known to be spiral galaxies, were likely to be more distant objects.

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STAR-FORMING NEBULAE Star formation can be seen throughout the Milky Way, but it is principally evident in the spiral arms and toward the galactic center, where there is an abundance of star-making ingredients: dust and gas. In these regions, the interstellar matter is dense enough for molecular clouds to exist. These clouds are cold and appear as dark nebulae that are visible only when framed against a brighter STELLAR NURSERY background. When stars are born, these clouds are Bright young stars within the illuminated from within to become emission nebulae, Omega Nebula, M17, light up the some of the most beautiful sights in the Milky Way. nebula from which they were born. DARK NEBULA

BHR 71 CATALOG NUMBER

BHR 71 DISTANCE FROM SUN

600 light-years

MUSCA

BINARY FORMATION

Jets from BHR 71’s newly forming binary star system have created the filamentary structure seen in this composite image made from four separate images.

DARK NEBULA

Horsehead Nebula CATALOG NUMBER

Barnard 33 DISTANCE FROM SUN

1,500 light-years

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ORION

One of the most beautiful and wellknown astronomical sights, the Horsehead Nebula can be located in the night sky just south of the bright star Zeta (ζ) Orionis, the left star of the three in Orion’s belt (see pp.390–91). The nebula is an extremely dense, cold, dark cloud of gas and dust, silhouetted against the bright, active nebula IC 434. It is about 16 light-years across and has a total mass about 300 times that of the Sun. The Horsehead shape is sculpted out of dense interstellar material by the radiation from the hot young star Sigma (σ) Orionis. Within the dark cloud, from which the Horsehead rears, is a scattering of young stars in the process of forming. The streaks that extend through the bright area above the Horsehead are probably caused by magnetic fields within the nebula.

DARK KNIGHT

One of the most photographed objects in the night sky, this dark nebula resembles the head of a sea horse or a knight on a chessboard. Its unusual shape was first discovered on a photographic plate in 1888.

The small dark nebula BHR 71 is called a Bok globule (see p.238) and has a diameter of about one light-year. Within the dark molecular cloud are two sources of infrared and radio rays believed to be very close embryonic stars: HH 320 and HH 321, both losing vast amounts of material as they collapse. HH 320 has the strongest outflow, and it is probably surrounded by a massive disk of previously ejected stellar material. Although not optically visible, HH 320 has ten times the luminosity of the Sun. BHR 71 and its protostars offer a rare opportunity for the study of star-formation processes.

STAR-FORMING NEBULAE

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EMISSION NEBULA

Orion Nebula CATALOG NUMBERS

M42, NGC 1976 DISTANCE FROM SUN

1,500 light-years MAGNITUDE

4

ORION

NEW STARS

At the top of this image are the Trapezium stars forming within the Orion Nebula. Also visible, toward the bottom left-hand corner, is a line of shock waves created by material outflowing from the embryonic stars at a speed of 450,000 mph (720,000 km/h).

The most famous and the brightest nebula in the night sky, the Orion Nebula is easily visible with the naked eye as a diffuse, reddish patch below Orion’s belt (see pp. 390–91). It is also the closest emission nebula to Earth and has been extensively studied. The nebula spans about 30 light-years and has an apparent diameter four times that of a full moon. However, it is a small part of a much larger molecular cloud system known as OMC-1, which has a diameter of several hundred light-years. The Orion Nebula sits at the edge of OMC-1, which stretches as far as the Horsehead Nebula (opposite). The nebula glows with the ultraviolet radiation of the new stars forming within it. Many of these stars have been shown to have protoplanetary disks surrounding them. The principal stars whose radiation is ionizing the cloud of dust and gas belong to the Trapezium star cluster (see p.391), located at the heart of the nebula. At about 30,000 years old, the Trapezium is one of the youngest clusters known. It is a quadruple star system consisting of hot OB stars (see pp.232–33). In 1967, an extended dusty region was discovered directly behind the Orion Nebula. Known as the Kleinmann– Low Nebula, it has strong sources of infrared radiation embedded within it. These sources are believed to be protostars and newly formed stars. EXPLORING SPACE

FIRST PHOTOGRAPH

This view was captured with the VISTA telescope in Chile. It is an infrared image, revealing newborn stars within the nebula’s dusty interior.

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THE GREAT ORION NEBULA

A pioneer of astrophotography, the American scientist Henry Draper (1837–82) took the first photograph of a nebula in September 1870 after he turned his camera to the Orion Nebula, the brightest one in the sky. Although his photograph was relatively crude, 12 years later he used an 11-in (28-cm) photographic refractor to obtain a much-improved image. The Orion Nebula has since been photographed probably more times than any other nebula.

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STAR-FORMING NEBULAE DARK NEBULA

Cone Nebula CATALOG NUMBER

NGC 2264 DISTANCE FROM SUN

2,500 light-years MAGNITUDE

3.9

MONOCEROS

Discovered by William Herschel in 1785, the Cone Nebula is a dark nebula located at the edge of an immense, turbulent star-forming region. This conical pillar of dust and gas is more than 7 light-years long and at its “top” is 2.5 light-years across. The Cone Nebula is closely associated with the star cluster NGC 2264, commonly known as the Christmas Tree Cluster. This cluster, CHRISTMAS TREE CLUSTER

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The stars of the open cluster NGC 2264 can be seen in this image resembling an upsidedown Christmas tree, with the Core Nebula (boxed) at the apex of the tree.

TOWER OF RESISTANCE

Born in immense clouds of dust and gas, the great tower of the Cone Nebula is a slightly denser region of material that has resisted erosion by radiation from its neighboring stars.

which spans a distance of 50 lightyears, is made up of at least 250 stars, and it is the light from some of its newborn stars that allows the Cone Nebula to be seen in silhouette. The Cone Nebula is located at the top of the Christmas Tree Cluster, pointing downward to the bottom of the tree. At the opposite end, the 5th-magnitude star S Mon marks the left of the base of the tree (see below left). Jets of stellar material thrown out by newly forming stars have been detected within the star cluster. These Herbig-Haro objects also help to shape the material in the surrounding nebula. One explanation for the shape of the Cone Nebula suggests that it was formed by stellar wind particles from an energetic source blowing past a Bok globule at the head of the cone. Buried in the dust and gas near

INFRARED IMAGING

Unseen in an optical image (left), a remarkable infrared view of the tip of the Cone Nebula (right) reveals, to the right of the image, a clutch of faint newborn stars.

the top of the Cone is a massive star known as NGC 2264 IRS, which is surrounded by six smaller Sunlike stars. It is thought that the outflow of stellar material during the early years of this massive star triggered the formation of the surrounding six and also helped to sculpt the shape of the Cone Nebula itself. None of these stars are visible with optical telescopes. Infrared observations have revealed further embryonic stars embedded in the nebulosity (above), making this one of the most active star-forming regions in this area of the Milky Way.

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EMISSION NEBULA

The Elephant’s Trunk Nebula is sculpted from a huge cloud of interstellar material in which star formation may take place in the future.

IC 1396 CATALOG NUMBER

IC 1396 DISTANCE FROM SUN

3,000 light-years

CEPHEUS

Occupying an area hundreds of lightyears across, the IC 1396 complex contains one of the largest emission nebulae close enough to be observed in detail. It has an apparent diameter in the night sky ten times that of a full moon. The mass of the nebula is estimated to be an immense 12,000 times the mass of the Sun, mainly consisting of hydrogen and helium in various forms. HD 206267, a massive, young blue star at the center of the region, produces most of the radiation that illuminates the nebula’s interstellar material. Observations have shown that ionized clouds form a rough ring around this star at distances between 80 and 130 light-years. These clouds are the remains of the molecular cloud that originally gave birth to HD 206267 and its siblings, which compose the star cluster known as Tr37. Tracts of cool, dark material lie farther away from HD 206267. Among the most dramatic of these

GIGANTIC STELLAR NURSERY

The immense IC 1396 complex of emission nebulae, dark nebulae, and a young star cluster is shown here in a composite image. Mu Cephei is located at the center, and the Elephant’s Trunk Nebula is boxed.

structures is one commonly known as the Elephant’s Trunk Nebula. Research suggests that some of this material has been blown away from the star by strong stellar winds, causing the material to form elongated structures such as the Elephant’s Trunk. Some of these structures stretch radially away from HD 206267 for up to 20 light-years. Within IC 1396 lies Mu (μ) Cephei, also known as Herschel’s Garnet Star. One of the largest and brightest stars known, Mu Cephei is a red supergiant emitting 350,000 times the power of the Sun.

EMISSION NEBULA

EMISSION NEBULA

DR6

Lagoon Nebula CATALOG NUMBER

CATALOG NUMBERS

DR6

M8, NGC 6523

DISTANCE FROM SUN

DISTANCE FROM SUN

4,000 light-years

light-years MAGNITUDE

5,200

6

SAGITTARIUS

Strong stellar winds from about 10 young stars at the center of this unusual nebula have created cavities within its interstellar material, making it resemble a human skull. The nebula has a diameter of about 15 light-years, and the “nose,” where the stars that have sculpted the nebula are located, is about 3.5 light-years across. The central group of stars is very young, having formed less than 100,000 years ago. The picture below is a composite of four infrared images.

The Lagoon Nebula is a productive star-forming region situated within rich, conspicuous fields of interstellar matter. Covering an apparent diameter of more than three full moons, the Lagoon Nebula is so large and luminous that it is visible to the naked eye. The region contains young star clusters, distinctive Bok globules (see p.238), and very energetic star-forming regions. There are also many examples of twistedrope structures thought to have been created by hot stellar winds colliding with cooler dust clouds. The bright center of the Lagoon Nebula is illuminated by the energy of several very hot young stars, including the 6th-magnitude 9 Sagittarii and the 9th-magnitude Herschel 36. Also found in the brightest region is the famous Hourglass Nebula (see p.263). The open cluster NGC 6530 (to the left of center in the main image) contains 50 to 100 stars that are only a few million years old. Clearly visible across the Lagoon Nebula are dark Bok globules.

TWISTS OF GAS

Creative chaos is revealed within the vast Lagoon Nebula, as radiation and strong winds from forming stars interact with surrounding clouds of interstellar dust and gas.

DARK GLOBULES

HOLLOW SKULL

One of the key features of the Lagoon Nebula is the presence of a large number of dark, comet-shaped clouds of collapsing dust and gas called Bok globules, where future stars may be born.

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CYGNUS

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STAR-FORMING NEBULAE EMISSION NEBULA

Eagle Nebula CATALOG NUMBER

IC 4703 DISTANCE FROM SUN

7,000 light-years MAGNITUDE

6

SERPENS

Observations of the Eagle Nebula have introduced new ideas into the theory of star formation. Lying in one of the dense spiral arms of the Milky Way, this is an immense stellar nursery where young stars flourish, new stars are being created, and the material and triggers exist for future star formation. In optical wavelengths, this region is dominated by the light from the bright young star cluster M16. This cluster was discovered by the Swiss astronomer Philippe Loys de Chéseaux in around 1745, but it was nearly 20 years later that the surrounding nebula, from which the star cluster had formed, was discovered by Charles Messier (see p.73). The star cluster itself is only about 5 million years old and has a diameter of about 15 light-years. The Eagle Nebula is much larger than the star cluster, with a diameter of about 70 light-years. In 1995, the Hubble Space Telescope imaged features within the nebula that are commonly known as the Pillars of Creation (see panel, below). These famous pillars are towers of dense material that have resisted evaporation by radiation from local young stars. However, the stars’ ultraviolet radiation is gradually boiling their surfaces away, through a process called photoevaporation. Since the towers themselves are not of a consistent density, the continuing photoevaporation has caused some of the smaller nodules, known as evaporating gaseous globules (EGGs), to become detached from the main gas towers. At this point, these dense stellar nurseries cease to accrue more material, and any embryonic star

HUGE STELLAR NURSERY

This wide-field image shows the immensity of the Eagle Nebula, with the three Pillars of Creation located near the center. This huge cloud of gas lies in the galaxy’s Sagittarius– Carina arm, toward the galactic center.

within has its upper mass limit fixed. It is thought that this type of star formation inhibits the formation of accretion disks around the stars, which are believed to be the material from which planets are formed. These detailed images of the Pillars of Creation were the first to suggest this process of star creation. The Eagle Nebula also contains many Bok globules, regions where future star formation is probably occurring.

EXPLORING SPACE

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THE PILLARS OF CREATION This image, taken by the Hubble Space Telescope in 1995, has become one of the most famous and iconic astronomical images. Revealing, for the first time in dramatic detail, a previously unsuspected process of star formation, it captured the public’s imagination and inspired a new interest in astronomy. The image’s aesthetic appeal and the sense of wonder it inspires have led to its being displayed on posters, in magazines, and even on stamps. STELLAR CLOSE-UP

These spectacular pillars of dust and gas are several light-years long but represent only a small section of the Eagle Nebula.

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TWISTED PILLARS

The three Pillars of Creation are shown twisting through a rich star field in this composite infrared image. Not all these stars are in the Eagle Nebula—some lie far behind and others lie in front.

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STAR-FORMING NEBULAE EMISSION NEBULA

IC 2944 CATALOG NUMBER

IC 2944 DISTANCE FROM SUN

5,900 light-years MAGNITUDE

4.5

CENTAURUS

Between the constellations Crux and Centaurus lies the bright, busy starforming nebula IC 2944. This nebula is made up of dust and gas that is illuminated by a loose cluster of massive young stars. IC 2944 is perhaps best known for the many Bok globules that are viewed in silhouette against its backdrop. Bok globules are thought to be cool, opaque regions of molecular material that will eventually collapse to form stars. However, studies of the globules in IC 2944 have

revealed that the material of which they are composed is in constant motion. This may be caused by radiation from the loose cluster of massive young stars embedded in IC 2944. The stars’ ultraviolet radiation is gradually eroding the globules, and it is possible that this could prevent them from collapsing to form stars. In addition to radiation, the stars also emit strong stellar winds that send out material at high velocities, causing heating and erosion of interstellar material. The largest Bok globule in IC 2944 (below) is about 1.4 lightyears across, with a mass about 15 times that of the Sun.

EMISSION NEBULA

DR 21 CATALOG NUMBER

DR 21 DISTANCE FROM SUN

6,000 light-years

CYGNUS

The birth of some of the Milky Way’s most massive stars has been discovered within DR 21, a giant molecular cloud spanning about 80 light-years. Infrared images have revealed an energetic group of newborn stars tearing apart the gas and dust around them. One star alone is 100,000 times as bright as the Sun. This star is ejecting hot stellar material into the surrounding molecular cloud, suggesting it may have a planet-forming disk around it.

THACKERAY’S GLOBULES

The Bok globules in IC 2944 were first observed in 1950 by South African astronomer A.D. Thackeray. This globule has recently been shown to be two overlapping clouds.

EMISSION NEBULA

Trifid Nebula CATALOG NUMBER

M20 DISTANCE FROM SUN

7,600 light-years MAGNITUDE

6.3

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SAGITTARIUS

This emission nebula is one of the youngest yet discovered. It was first called the Trifid Nebula by English astronomer John Herschel because of its three-lobed appearance when seen through his 18th-century telescope. The nebula is a region of interstellar dust and gas being illuminated by stars forming within it. It spans a distance of around 50 light-years. The young star cluster at its center, NGC 6514, was formed only about 100,000 years ago. The Trifid’s lobes, the brightest of which is actually a multiple system, are created by dark filaments lying in and around the bright nebula. The whole area is surrounded by a blue reflection nebula, particularly conspicuous in the upper part, where dust particles disperse light. HEART OF THE TRIFID

The main image, spanning about 20 lightyears, reveals details of the NGC 6514 star cluster and the filaments of dust weaving through the Trifid Nebula. A wider view (above) shows the full breadth of the nebula.

GIGANTIC EMBRYOS

This infrared image reveals a clutch of gigantic newborn stars, shown here in green. In optical light, the surrounding molecular cloud is opaque.

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Carina Nebula CATALOG NUMBER

NGC 3372 DISTANCE FROM SUN

8,000 light-years MAGNITUDE

1

CARINA

Also known as the Eta (η) Carinae Nebula, this is one of the largest and brightest nebulae to be discovered. It has a diameter of more than 200 lightyears, stretching up to 300 light-years if its fainter outer filaments are included. Within its heart, and heating up its dust and gas, is an interesting zoo of young stars. These include examples of the most massive stars known, with a spectral type of O3 (see pp.232–33). This type of star was first discovered in the Carina Nebula, and the nebula remains the closest location of O3 stars to Earth. Also within the Carina Nebula are three Wolf–Rayet stars with spectral type WN (see pp.254–55). These stars are believed to be evolved O3 stars with very large rates of mass ejection. One of the best-known features within the Carina Nebula is the blue supergiant star Eta (η) Carinae (see p.262), embedded within part of the nebula known as the Keyhole Nebula. Recent observations made with infrared

PROBING THE NEBULA

An infrared image reveals the stars lying within the nebula’s dense dust and gas. The open clusters Trumpler 14 and Trumpler 16 are visible to the left and top of the image.

telescopes reveal that portions of the Carina Nebula are moving at very high speeds—up to 522,000 mph (828,000 km/h)—in varying directions. Collisions of interstellar clouds at these speeds heat material to such high temperatures that it emits high-energy X-rays, and the entire Carina Nebula is a source of extended X-ray emission. The movement of these clouds of material is thought to be due to the strong stellar winds emitted by the massive stars within, bombarding the surrounding material and accelerating it to its high velocities. ERODING TOWER

A tower of cool hydrogen gas and dust three light-years long extends from the Carina Nebula in this false-color Hubble image. The tower is being eroded by the energy from hot, young stars nearby.

COSMIC CONSTRUCTION

EMISSION NEBULA

RCW 49 CATALOG NUMBERS

RCW 49, GUM 29 DISTANCE FROM SUN

14,000 light-years

This false-color image, composed of four separate images taken in different infrared wavelengths, reveals more than 300 newborn stars scattered throughout the RCW 49 nebula. The oldest stars of the nebula appear in the center in blue, gas filaments appear in green, and dusty tendrils are shown in pink. EXPLORING SPACE

CARINA

SPITZER TELESCOPE Launched in August 2003, the Spitzer telescope is one of the largest infrared telescopes put into orbit. It has been very successful in probing the dense dust and gas that lies in the interstellar medium and has revealed features and details within star-forming clouds that have never been seen before. As Spitzer observes in infrared, its instruments are cooled almost to absolute zero, to ensure that their own heat does not interfere with the observations. A solar shield protects the telescope from the Sun. INSIDE SPITZER

The Spitzer craft has a 34-in (85cm) telescope and three supercooled processing instruments.

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One of the most productive regions of star formation to have been found in the Milky Way, RCW 49 spans a distance of about 350 light-years. It is thought that over 2,200 stars reside within RCW 49, but because of the nebula’s dense areas of dust and gas, the stars are hidden from view at optical wavelengths of light. However, the infrared telescope onboard the Spitzer spacecraft (see panel, right) has recently revealed the presence of up to 300 newly formed stars. Stars have been observed at every stage of their early evolution in this area, making it a remarkable source of data for studying star formation and development. One surprising preliminary observation suggests that most of the stars have accretion disks around them. This is a far higher ratio than would usually be expected. Detailed observations of two of the disks reveal that they are composed of exactly what is required in a planet-forming system. These are the farthest and faintest potential planet-forming disks ever observed. This discovery supports the theory that planet-forming disks are a natural part of a star’s evolution. It also suggests that solar systems like our own are probably not rare in the Milky Way (see pp.296-99).

THE CARINA NEBULA

A maelstrom of star birth, and death, is seen in this false-color view of the Carina Nebula from the Hubble Space Telescope. Stellar winds and ultraviolet radiation sculpt the nebula into fantastic shapes. The nebula contains at least a dozen stars that are 50 to 100 times the mass of the Sun. Among them is Eta Carinae (see p.254), on the center left edge, a star on the verge of instability.

250

MAIN-SEQUENCE STARS

MAIN-SEQUENCE STARS MAIN-SEQUENCE STARS

232–33 Stars 234–37 The life cycles of stars 239 Towards the main sequence Old stars 254–55 Stellar end points 266–67

are those that convert hydrogen into helium in their cores by nuclear reactions. Stars spend a high proportion of their lives on the main sequence, STAR FLARES during which time they are very stable. The The Sun’s photohigher the mass of the star, the less time it sphere radiates huge amounts of energy as spends on the main sequence, as nuclear solar flares contribute reactions occur faster in higher-mass stars. to the solar wind.

STAR ENERGY

STELLAR STRUCTURE

The cores of main-sequence stars initially consist mainly of hydrogen. When the temperature and pressure become high enough, the hydrogen is converted into helium by nuclear reactions. For stars of less than about 1.5 solar masses, this is done by means of a process called the proton–proton chain reaction (the pp chain). For stars of more than about 1.5 solar masses and with core temperatures of more than about 36 million °F (65 million °C), carbon, nitrogen, and oxygen are used as catalysts in a process called the carbon cycle (CNO cycle). When hydrogen is converted to helium, a tiny amount of energy is released as gamma rays, which gradually permeate their way out through the photosphere (the Sun’s visible surface). The huge amounts of energy radiated by main-sequence stars are due to the immense masses of hydrogen they contain. In the core of the Sun, 600 million tons of hydrogen are converted into helium every second.

Energy, in the form of gamma rays, is released in the nuclear reactions occurring within stellar cores. This energy can be transported outward by two processes: convection and radiation. In convection, hot material rises to cooler zones, expanding and cooling, then sinks back to hotter levels, just like water being boiled in a saucepan. In the radiation process, photons are continually absorbed and reemitted. They can be emitted in any direction, and sometimes travel back into the central core. They follow a path termed a “random walk,” but gradually diffuse outward, losing energy as they do so. Their energy matches the temperature of the surrounding material, so they start as gamma photosphere rays, but at the Sun’s surface, the photosphere, they appear in the visible part of the convective zone electromagnetic spectrum. large radiative zone

MASSIVE STAR

Achernar, or Alpha (α) Eridani, the ninth-brightest star in the sky, is a blue main-sequence star of about six to eight solar masses. Main-sequence stars of this size convert hydrogen to helium through a process called the carbon cycle.

ERUPTIVE SURFACE

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Main-sequence stars, such as the Sun, appear smooth in optical light, but in reality their photospheres are extremely turbulent with huge prominences of material constrained by magnetic fields.

small convective core

photosphere energy produced in core

radiative zone

HIGH-MASS STAR

LOW-MASS STAR

Stars with a mass greater than 1.5 solar masses produce energy through the CNO cycle. They have convective cores and a large radiative zone reaching to the photosphere.

In stars with a mass smaller than 1.5 solar masses, the pp chain dominates, and a large, inner radiative zone reaches out to a smaller convection zone near the star’s photosphere.

MAIN-SEQUENCE STARS

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ROTATION AND MAGNETISM The pressures and temperatures within stars mean they are composed of plasma (see p.30). Within this ionized matter, negatively charged electrons travel free from the positively charged ions. This has a profound effect on magnetic fields, since charged particles do not cross magnetic field lines easily. Magnetic field lines can dictate the movement of stellar material, but the movement of the plasma can also affect magnetic fields. sun-spot group All stars rotate, and some spin so fast they bulge out at the equator and has rotated from are very flattened at the poles. As stars rotate, magnetic-field lines are previous position carried around by the plasma. This “winds up” the magnetic field and region of equal creates pockets of intense magnetic flux where field lines area to the Earth are brought close together. The movement of stellar SOLAR ROTATION material and the transfer of heat is restricted in these As the Sun rotates, sun-spot groups are areas, so they are appreciably cooler than the surrounding observed traveling across its disk. Mainsequence stars rotate differentially, with material. As they are cooler, they appear dark against the material at the equator rotating faster rest of the photosphere. Dark star spots on the surface of than that at the poles. On the Sun, stars are areas of intense activity, because the buildup of sunspots closer to the equator travel heat around them can suddenly be released as flares. across the solar disk more rapidly.

British astronomer Arthur Stanley Eddington (1882–1944) studied the internal structure of stars and derived a mass–luminosity relationship for main-sequence stars. In 1926, he published The Internal Constitution of Stars, in which he suggested that nuclear reactions were the power source of stars. While working at the Royal Greenwich Observatory, Eddington led two expeditions to view total solar eclipses and in 1919 provided evidence for the theory of general relativity. Eddington also calculated the abundance of hydrogen within stars and developed a model for Cepheid variable pulsation (see p.282). He became Plumian professor of astronomy at Cambridge in 1913 and director of the Cambridge Observatory in 1914. He was knighted in 1930.

THE MAIN SEQUENCE A star enters the main sequence when it starts to burn hydrogen in its core. As soon as the nuclear reactions instigating this process begin, it is said to be at age zero on the main sequence. A star’s life on the main sequence is very stable, with the pressure from the nuclear reactions in its core being balanced by its gravity trying to compress all of its mass into the center. A star will spend most of its life on the main sequence, and consequently about 90 percent of the stars observed in the sky are main-sequence stars. A star’s time on the main sequence is dependent on its mass. The more massive the star, the hotter and denser its core and the faster it will convert hydrogen into helium. The Sun is a relatively small main-sequence star and will be on the main sequence for about ten billion years. A ten-solar-mass star will be on the main sequence for only ten million years. While on the main sequence, a star will conform to the mass–luminosity relation, which means that the absolute magnitude or luminosity of a star will give an indication of its mass. As it converts hydrogen into helium, a star’s chemical composition and internal structure will change and it will move slightly to the right of its zero-age position on the H–R diagram (below). As soon as the hydrogen in the core is depleted, and hydrogen burning in the atmosphere begins, the star leaves the main sequence (see p.236). 10 6

DIAGONAL PATH

The main sequence is a diagonal curving path of stars on the Hertzsprung– Russell diagram, a simplified version of which is shown here (see also p.232). The curve runs from bottom right (low mass and cool) to top left (massive and hot). Each star has a “zero-age” position (a point on the curve indicating its mass and temperature). It hardly strays at all from this position during its time on the main sequence.

10 5 10

60 solar masses

4

30 solar masses MAIN SEQUENCE

10 solar masses

10 3

6 solar masses 10 2 3 solar masses

Spica 10

1.5 solar masses

Achernar

1 solar mass

1

Sirius Sun

0.1

0.3 solar masses

10 -2 0.1 solar masses

10 -3 10 -4

Proxima Centauri

10 -5 30,000

10,000

5,000

3,000

SURFACE TEMPERATURE OF STAR (°C)

TH E MI L KY WAY

LUMINOSITY OF STAR (SOLAR UNITS)

ARTHUR EDDINGTON

252

MAIN-SEQUENCE STARS

MAIN-SEQUENCE STARS During a star’s life, it passes through many phases, but most of its time will be spent on the main sequence. This means that the chances of seeing any star are greatest during its main-sequence life time. In fact, about 90 percent of all observed stars are on the main sequence. Although PROMINENT STARS main-sequence stars are spread throughout the Known as the Pointers, Alpha and Beta Centauri are prominent mainMilky Way, they appear predominantly in its sequence stars guiding the way plane and central bulge. to the Southern Cross. ORANGE-RED STAR

Proxima Centauri DISTANCE FROM SUN

4.2 light-years MAGNITUDE

11.05

SPECTRAL TYPE

M

by about one magnitude (see pp.282–83). Even when in eruption, it is very faint—18,000 times dimmer than the Sun—but it is an intense source of low-energy X-rays and high-energy ultraviolet rays. With a low luminosity and small size, it was not discovered until 1915. It has only about a tenth the mass of the Sun, and is a good example of a main-sequence star nearing the end of its life.

YELLOW AND ORANGE STARS

Alpha Centauri

Sirius A

DISTANCE FROM SUN

DISTANCE FROM SUN

4.3 light-years MAGNITUDES

8.6 light-years

0.0 and 1.3

SPECTRAL TYPES

MAGNITUDE

G and

-1.46

SPECTRAL TYPE

A

K

CENTAURUS

CENTAURUS

CANIS MAJOR

The closest star to the Sun, Proxima Centauri is thought to be a member of the Alpha Centauri system (right), orbiting the binary system at a distance 10,000 times the distance of Earth from the Sun. Its orbital period is at least one million years, prompting some astronomers to question whether Proxima is gravitationally bound to Alpha Centauri at all. Proxima is a flare star, a cool red dwarf that undergoes outbursts of energy, when it brightens

The two stars of Alpha Centauri—also known as Rigil Kentaurus—orbit each other every 79.9 years. They are very close, and, in some images (below), are distinguishable only by seeing two sets of diffraction spikes. Alpha Centauri A is the brighter and more massive, at 1.57 times the luminosity and 1.1 times the mass of the Sun. Alpha Centauri B is both less massive and less luminous than the Sun.

The brightest star in the night sky, Sirius is the ninth-closest star to Earth. It is a binary star, with Sirius A being a main-sequence star and its companion a white dwarf. Sirius A has twice the mass of the Sun and is 23 times as luminous. Recent observations suggest that it may have a stellar wind—the first spectral type A star to show evidence of one.

POSSIBLE PLANET

SCORCHING STAR

Small variations in Proxima Centauri’s movement across the sky have suggested that it may be orbited by a planet with a mass 80 percent that of Jupiter.

A false-color image shows the diffraction pattern of Sirius, the brightest star in the sky. Its name is from the Greek for “scorching.”

ALPHA CENTAURI A AND B

WHITE STAR

ORANGE STAR

Altair

61 Cygni

DISTANCE FROM SUN

DISTANCE FROM SUN

16.8 light-years

11.4 light-years MAGNITUDES

5.2 and 6.1

SPECTRAL TYPE

MAGNITUDE

K

0.77

SPECTRAL TYPE

A

T HE M I LK Y WAY

WHITE STAR

CYGNUS

AQUILA

61 Cygni is a binary system of two main-sequence stars that orbit each other every 653 years. It is believed that 61 Cygni has at least one massive planet and possibly as many as three. In 1838, German astronomer Friedrich Bessel became the first to measure the distance of a star from Earth accurately, when he calculated 61 Cygni’s annual parallax (see p.70). He chose 61 Cygni because, at that time, it was the star with the largest known FAST STAR proper motion.

One of the three stars of the Summer Triangle, Altair is the 12th-brightest star in the sky. With a diameter about 1.6 times that of the Sun, it rotates once every 6.5 hours. This puts its equatorial spin rate at about 559,000 mph (900,000 km/h), which causes distortion of its overall shape. This distortion is such that the star becomes wider at the equator and flattened at the poles, and estimates have suggested that its equatorial diameter is as much as double its polar diameter. It has a surface temperature of about 17,000°F (9,500°C) and a high rate of proper motion through the Milky Way.

DUSTY BACKDROP

In this optical image, Altair (boxed), the brightest star in Aquila, the Eagle, shines out against the dusty backdrop of the Milky Way.

253 WHITE STAR

WHITE STAR

Fomalhaut

Vega DISTANCE FROM SUN

DISTANCE FROM SUN

25.1 light-years MAGNITUDE

25.3 light-years

1.16

SPECTRAL TYPE

MAGNITUDE

A

0.03

SPECTRAL TYPE

A

ORBITING PLANET PISCIS AUSTRINUS

Fomalhaut b is seen here in a Hubble Space The brightest star in Piscis Austrinus, Telescope image. Light 2004 2006 Fomalhaut is the 18th-brightest star in from Fomalhaut itself the sky. It has a surface temperature of has been blocked out. In the enlargement (right), the planet is seen about 15,000°F (8,500°C), with a to have moved between 2004 and 2006. luminosity 16 times that of the Sun.

In 1983 the infrared telescope IRAS revealed that it was a source of greater infrared radiation than expected.

YELLOW-WHITE STAR

Further observations revealed that the infrared radiation is being emitted by a ring of dust particles—with a diameter over twice that of the Solar System—around Fomalhaut. Within the inner edge of this ring, the Hubble Space Telescope has detected a planet 10.7 billion miles (17.2 billion km) from the star. The planet, called Fomalhaut b, has an estimated orbital period of 872 years and a mass no more than three times that of Jupiter.

BRIGHT BEACON

Fomalhaut, the “mouth of the fish,” is the most distinctive star in the constellation Piscis Austrinus.

The brightest star in the northern summer sky, Vega takes its name from an Arabic word meaning “swooping eagle.”

Regulus DISTANCE FROM SUN

DISTANCE FROM SUN

38 light-years

78 light-years

MAGNITUDE

0.36

SPECTRAL TYPE

MAGNITUDE

F

VIRGO

1.35

SPECTRAL TYPE

B

LEO

The brightest star in the constellation Leo, Regulus just makes it into the top 25 brightest stars as seen from Earth. Regulus is a Latin word meaning “little king.” The star is situated at the base of the distinctive sickle asterism (shaped like a reversed question mark) in the constellation. It lies very close to the ecliptic (see pp.62–65) and is often occulted by the Moon (right). Regulus is a triple system. The brightest component is a blue-white THE PORRIMA PAIR

main-sequence star about 3.5 times the mass of the Sun and with a diameter also around 3.5 times that of the Sun. It has a surface temperature of about 22,000°F (12,000°C) and shines at about 140 times the brightness of the Sun. It is also an emitter of high levels of ultraviolet radiation. Regulus has a companion binary star, composed of an orange dwarf and a red dwarf separated by about 9 billion miles (14 billion km). These dwarf components orbit each other over a period of about 1,000 years, and they in turn orbit the main star once every 130,000 years. REGULUS OCCULTED

Poised at the top-left curve of the Moon, Regulus is about to be occulted as the Moon passes in front of it. Occultations can help astronomers to determine the diameters of large stars and ascertain whether they are binary systems. Occultations by the Moon can also reveal details about the Moon’s surface features.

BLUE STAR

Gamma Velorum DISTANCE FROM SUN

840 light-years MAGNITUDE

1.8

SPECTRAL TYPES

O and

WR

VELA

This blue star is also sometimes known as Regor – “Roger” spelled backwards – in honour of the astronaut Roger Chaffee, who died in a fire during a routine test on board the Apollo 1 spacecraft in 1967. Gamma (γ) Velorum, is a complex star system dominated by a blue subgiant poised to evolve off the main sequence. Its evolution has been affected by being in a very close binary orbit with a star that is now a Wolf–Rayet star. They lie as close as Earth does to the Sun and orbit each other every 78.5 days. The Wolf–Rayet star is now the less massive component of the close binary, but probably started as the more massive and evolved much more rapidly. The subgiant has around 30 times the mass of the Sun, with a surface temperature of 60,000°F (35,000°C) and a luminosity around 200,000 times that of the Sun. There are also two other components to the system, lying much farther away, one of which is a hot B-type star (see pp. 232–33) at a distance of about 0.16 light-years.

TH E MI LKY WAY

Porrima, also known as Gamma (γ) Virginis, is a binary system made up of two almost identical stars, both about 1.5 times the mass of the Sun. Their surface temperatures are around 13,000°F (7,000°C) and they appear creamy white in amateur telescopes. Their luminosities are each about four times that of the Sun. They orbit each other in a very elliptical path that takes around 170 years to complete.

Also known as Alpha (α) Lyrae, Vega is the fifth-brightest star in the sky. Along with Altair (opposite) and Deneb, it makes up the Summer Triangle. Vega has a mass of about 2.5 solar masses, a luminosity 54 times that of the Sun, and a surface temperature of about 16,500°F (9,300°C). Around 12,000 years ago, it was the north Pole Star, and it will be so again in about 14,000 years. In 1983, the infrared satellite IRAS revealed that it is surrounded by a disk of dusty material that is possibly the precursor to a planetary system. Vega is the ultimate “standard” star, used to calibrate the spectral range and apparent magnitude of stars in optical astronomy (see p.233).

DISTINCTIVE STAR

BLUE-WHITE STAR

Porrima

LYRA

254

OLD STARS

OLD STARS OLD STARS INCLUDE

low-mass main-sequence stars that came into existence billions of years 234–37 The life cycles of stars ago and also some high-mass stars that will Stellar end points 266–67 explode as supernovae after existing for The role of black holes 307 less than a million years. Some of the most beautiful sights in the Milky Way are old stars undergoing their death throes. 232–33 Stars

RED GIANTS When a star has depleted the hydrogen in its core, it will start to burn the hydrogen in a shell surrounding the core. This shell gradually moves outward through the atmosphere of the star as fuel is used up. The expanding source of radiation heats the outer atmosphere, which expands, and then cools. The result is a large star EVOLVED STARS with a relatively low surface temperature. It is easy to pick out the It remains luminous because of its huge evolved red giant stars in size, though some red giants are hidden this image of the ancient star cluster NGC 2266. from view by extensive dust clouds. Red giants have surface temperatures of 3,600–7,200°F (2,000–4,000°C) and radii 10–100 times that of the Sun. Because they are so large, gravity does not have much effect on their outer layers and they can lose a great deal of mass to the interstellar medium, either by stellar winds or in the form of planetary nebulae. Red giants are often variable stars; their outer layers pulsate, causing changes in luminosity (see p.282). INSIDE A RED GIANT

A red giant’s helium core is contained by an inert helium shell. Outside this zone, a shell of hydrogen is being converted into helium, and this is surrounded by an outer envelope of hydrogen.

convection cells carry heat from core to surface

size of a large red giant star

orbit of Earth orbit of Mars orbit of Jupiter the Sun

core of helium

sooty grains of dust hot spot of escaping gas

size of a typical supergiant star

orbit of Saturn

ENORMOUS STARS

In place of the Sun, a red giant would reach beyond the orbit of the Earth, while a supergiant would have a radius reaching out to Jupiter’s orbit.

TH E M I LKY WAY

SUPERGIANTS Stars of very high mass expand to become even larger than red giants. Red supergiants can have radii several hundred times that of the Sun. Just like red giants, they undergo hydrogen-shell burning (see p.236) and leave the main sequence (see p.232). When they have finished hydrogen-shell burning, they collapse and the helium core reaches a high enough temperature for the helium to be converted into carbon and oxygen. Helium-core burning is briefer than hydrogen burning, and when the helium core is depleted, helium-shell burning begins. If massive enough, further nuclear burning will occur, producing GARNET STAR elements with an atomic mass up to that of iron. One of the largest stars visible in the Near the end of the supergiant phase, a high-mass night sky, Mu Cephei or the Garnet star will develop several layers of increasingly heavy Star is a red supergiant with a radius elements. Eventually, supergiants die as supernovae. greater than that of Jupiter’s orbit.

255 SUPERGIANT STARS

HELIUM FLASHING

GIANT STARS

Cepheids Mira stars Instability strip

RR Lyrae stars ABSOLUTE MAGNITUDE

Once hydrogen burning has produced a core of helium, if its temperature reaches higher than about 180 million °F (100 million °C), the helium will be fused together to form carbon. In stars of around two to three solar masses, helium burning can start in an explosive process called a helium flash. As the core collapses after hydrogen burning, it temporarily arrives at a dormant or “degenerate” state as the collapse is halted by the pressure between the helium’s electrons. The temperature continues to INSTABILITY STRIPS rise, but the dormant core does not change in Many red giants and pressure, so does not expand and cool. The supergiants are pulsating rising temperature causes the helium to burn variable stars that appear in regions of at an increasing rate, causing a “flash” that the H–R diagram (right, rids the core of the degenerate electrons. see also p.232) called In higher-mass stars, the temperature rises instability strips. Three high enough for helium fusion to begin types of variable star before the core becomes degenerate. are shown here.

Instability strip MAIN SEQUENCE

WHITE DWARFS SURFACE TEMPERATURE OF STAR

WOLF–RAYET STARS Massive stars, of about ten solar masses, that have strong, GREAT ILLUMINATION A Wolf–Rayet star illuminates the broad emission lines in their spectra (see p.35), but few heart of N44C, a nebula of glowing absorption lines, are named Wolf–Rayet stars, after Charles hydrogen gas Wolf and Georges Rayet (see p.264), who discovered surrounding young them in 1867. They are hot, luminous stars whose strong stars in the Large stellar winds have blown away their outer atmospheres, Magellanic Cloud. revealing the stars’ inner layers. They are broadly classified as WN, WC, and WO stars, depending on their spectra. The emission lines of WN stars are dominated by hydrogen and nitrogen, those of WC stars by carbon and helium, and those of WO by oxygen as well as carbon and helium. More than half of the known Wolf–Rayet stars are members of binary systems (see pp.274–75) with O or B stars as companions. It is believed that the Wolf-Rayet STRONG WINDS star was originally the more The planetary nebula NGC 6751 may have massive partner but lost its outer a Wolf–Rayet star at its center. Its strong winds created the elaborate filaments. envelope to the companion star.

PLANETARY NEBULAE

The dim star at the center of this image has produced the ring-shaped nebula around it. The nebula (NGC 3132) is crossed by dust lanes and surrounded by a cooler gas shell.

TH E MI L KY WAY

RING-SHAPED NEBULA

Planetary nebulae are heated halos of material shed by dying stars. They were termed planetary nebulae by William Herschel in 1785 because of their disklike appearance through 18th-century telescopes. Planetary nebulae include some of the most stunning sights in the universe, contorted into various shapes by magnetic fields and the orbital motion of binary systems (see p.274–75). They are composed of lowBUTTERFLY NEBULA density gas thrown off by low-mass stars in the red-giant The Hubble 5 nebula is a prime phase of their lives, and this gas is heated by the ultraviolet example of a “butterfly” or biradiation given off by the hot inner cores of the dying stars. polar nebula, created by the This stage of a star’s life is relatively short. Eventually, the funneling of expanding gas. planetary nebula will disperse back into the interstellar medium, enriching the material there with the elements that have been produced by its parent star. These elements include hydrogen, nitrogen, and oxygen. At one time, the oxygen identified in the emission spectra of planetary nebulae (see p.35) was regarded as a new element called nebulium. It was later realized that “forbidden” emission lines of oxygen were present—forbidden because under usual conditions on Earth, they are very unlikely to occur. The central stars of planetary nebulae are among the hottest stars known. They are the contracting cores of red giants evolving into white dwarfs. Some planetary nebulae have been observed surrounding the resulting white dwarf. Current studies of planetary nebulae are revealing new facts about the late evolution UNUSUAL NEBULA of red giants and the The Saturn Nebula was shaped by manner of mass loss early ejected material confining from these aging stars. subsequent stellar winds into jets.

256

OLD STARS Some of the most visible and familiar bodies in the sky are stars that are approaching the ends of their lives or are experiencing their final death throes. In Wolf–Rayet stars and planetary nebulae, these old stars also present some of the most dramatic events and most beautiful sights in the universe. Although different types of old stars exist throughout the Milky Way, the oldest are situated far DYING STAR Eta Carinae is a large, extremely old, out in the galactic halo (see pp.226–29) or within and unstable star ejecting material into the globular clusters (see pp.285). Some of these stars the interstellar medium. It could explode are nearly as old as the universe itself. as a supernova at any time. RED GIANT

RED SUPERGIANT

Betelgeuse

Aldebaran DISTANCE FROM SUN

DISTANCE FROM SUN

67 light-years MAGNITUDE

500 light-years

0.85

SPECTRAL TYPE

MAGNITUDE

K5

M2

TAURUS

ORION

Also known as Alpha (α) Tauri, Aldebaran is the brightest star in the constellation Taurus and the 13thbrightest star in the sky. Its surface temperature of only 6,740°F (3,730°C) makes it glow a dull red that can easily be seen by the naked eye. Aldebaran’s diameter is about 45 times that of the Sun, and, in place of the Sun, it would extend halfway to the orbit of Mercury. The star appears to be part of the Hyades cluster (see p.290), but this is a line-of-sight effect, with Aldebaran lying about 40 light-years closer to the Sun. This elderly star is a slow rotator, taking two years for each rotation, and an irregular variable, pulsating erratically. It has at least two faint stellar companions. Its name is derived from the Arabic Al Dabaran, meaning “the Follower,” because it rises after

The right shoulder of the hunter, Orion, is marked by this distinctive, bright red star. Betelgeuse, or Alpha (α) Orionis, is a massive supergiant and the first star after the Sun to have its size reliably determined. Its diameter is more than twice that of the orbit of Mars, or about 500 times that of the Sun, and because of its huge size it is about 14,000 times brighter. Betelgeuse is the 10th-brightest star in the sky, although as it pulsates its brightness varies over a period of about six years.

BULL’S EYE

The red tinge of Aldebaran makes it very distinctive against the whiter stars of the Hyades cluster. It is often depicted as the eye of the bull in the constellation Taurus.

the prominent Pleiades star cluster and pursues it across the sky. Aldebaran was one of the Royal Stars or Guardians of the Sky of ancient Persian astronomers and marked the coming of spring.

RED SUPERGIANT

SURFACE SPOTS

The infrared image of Betelgeuse above shows bright surface spots that could be convection cells. The infrared image at left shows gas and dust shed by the star, which has been masked by a black disk so that the gas and dust are visible.

It is a strong emitter of infrared radiation, which is produced by three concentric shells of material ejected by the star over its lifetime. It is slowly using up its remaining fuel and one day will probably explode as a supernova. RED GIANT

A RIVAL OF MARS

Antares DISTANCE FROM SUN

520 light-years MAGNITUDE

0.96

SPECTRAL TYPE

TH E MI L KY WAY

0.5

SPECTRAL TYPE

The glowing Antares (bottom right) looks a lot like Mars, the red planet. Its name derives from the Greek for “rival of Mars” (or anti Ares).

TT Cygni DISTANCE FROM SUN

1,500 light-years MAGNITUDE

M1.5

7.55

SPECTRAL TYPE

G

SCORPIUS

CYGNUS

Antares or Alpha (α) Scorpii is the 15th-brightest star in the sky. Estimates of its diameter range from 280 to 700 times that of the Sun. It is about 15 times more massive than the Sun and shines 10,000 times brighter. This elderly star pulsates irregularly and has a binary companion that orbits in a period of about 1,000 years. This companion lies close enough to be affected by Antares’ stellar wind and is a hot radio source. When viewed through an optical telescope, this blue companion looks green because of the color contrast with red Antares.

With a high ratio of carbon to oxygen in its surface layers, TT Cygni is known as a carbon star. The carbon, produced during helium burning, has been dredged up from inside the star. An outer shell, about half a light-year across, was emitted about 6,000 years before the star was as it appears to us now. CARBON RING

This false-color image shows a shell of carbon monoxide surrounding the carbon star TT Cygni.

257 PLANETARY NEBULA

GLOWING HALO

Helix Nebula CATALOG NUMBER

NGC 7293 DISTANCE FROM SUN

Rings of expelled material glow red in the light produced by nitrogen and hydrogen atoms when they are energized by ultraviolet radiation.

Up to 650 light-years MAGNITUDE

6.5

AQUARIUS

The Helix Nebula is the closest planetary nebula to the Sun, but its actual distance is uncertain, and estimates vary from 85 to 650 lightyears. It is called the Helix Nebula because, from Earth, the outer gases of the star expelled into space give the impression that we are looking down the length of a helix. One of the largest known planetary nebulae, its main rings are about 1.5 light-years in diameter and span an apparent distance of more than half the width of a full moon. Its outer halo extends up to twice this distance. The dying star at the center of the nebula is destined to become a white dwarf, and as it continues to use up all its energy it will continue to expel material into the interstellar medium. The Helix Nebula presents an impressive example of the final stage that stars like our Sun will experience before collapsing for the last time. It was first discovered by the German astronomer Karl Ludwig Harding in around 1824, and its size and proximity mean that it has been extensively observed and imaged.

PLANETARY NEBULA

Ring Nebula CATALOG NUMBER

M57 DISTANCE FROM SUN

2,000 light-years MAGNITUDE

8.8

LYRA

appears to be about one light-year in diameter, but it has an outer halo of material that extends for more than two light-years. This is possibly a remnant of the central star’s stellar winds before the nebula itself was ejected. The nebula is lit by fluorescence caused by the large amount of ultraviolet radiation emitted by the central star. The rate of the ring’s expansion indicates that the nebula started to form about 20,000 years before it was as it appears to us now. TRUE COLORS

An optical view shows the Ring Nebula in its true colors. Blue indicates very hot helium, green represents ionized oxygen, and red is ionized nitrogen. The star that produced the nebula, now a white dwarf, is visible at the center.

COMET-LIKE KNOTS

Resembling comets, these tadpole-shaped gaseous knots are several billion miles across. They lie like spokes in a wheel along the inner edge of the ring of ejected gas surrounding the central star.

PLANETARY NEBULA

Twin Jet Nebula CATALOG NUMBER

M2–9 DISTANCE FROM SUN

2,100 light-years MAGNITUDE

14.7

OPHIUCHUS

The Twin Jet Nebula is one of the most striking examples of a butterfly or bipolar planetary nebula. It is believed that the star at the center of this nebula is actually an extremely close binary that has affected the shape of the resulting planetary nebula. The gravitational interaction between the stars has pulled stellar

material around them into a dense disk with a diameter about 10 times that of Pluto’s orbit. About 1,200 years before this happened, one of the stars had an outburst, ejecting material in a strong stellar wind. This rammed into the disk, which acted like a nozzle, deflecting the material in perpendicular directions, forming the two lobes stretching out into space. This is very similar to the process that takes place in jet propulsion engines. Studies have suggested that the nebula’s size has increased steadily with time and that the material is flowing outward at up to 450,000 mph (720,000 km/h). EXHAUST JETS

This false-color image reveals apparent jets of material radiating outward. Neutral oxygen is shown in red, ionized nitrogen in green, and ionized oxygen in blue.

TH E M I LKY WAY

One of the best known planetary nebulae, the Ring Nebula was discovered in 1779 by French astronomer Antoine Darquier de Pellepoix. When seen through a small telescope, it appears larger than the planet Jupiter. Its central star, a planetsized white dwarf of only about 15th magnitude, was not discovered until 1800, when it was found by German astronomer Friedrich von Hahn. There has been a great deal of discussion about the true shape of the Ring Nebula. Although it appears like a flattened ring, some astronomers believe the stellar material has been expelled in a spherical shell that only looks like a ring because we view it through a thicker layer at its edges. Others believe it is a torus (shaped like a ring doughnut), which would look similar to the Dumbbell Nebula if viewed side-on, or that it is cylindrical or tubelike. The nebula

Detailed images made of the inner edge of the ring of material surrounding the central star have shown “droplets” of cooler gas, twice the diameter of our solar system, radiating outward for billions of miles. These were probably formed when a fast-moving shell of gas, expelled by the dying star, collided with slowermoving material thrown off thousands of years before.

258

OLD STARS PLANETARY NEBULA

Red Rectangle Nebula CATALOG NUMBER

HD 44179 DISTANCE FROM SUN

2,300 light-years MAGNITUDE

9.02

MONOCEROS

Nature does not often create rectangles, so astronomers were surprised to observe this planetary nebula’s unusual shape. The shape of the Red Rectangle nebula is created by a pair of stars orbiting so close to each other that they experience gravitational interactions. This close binary star has created a dense disk of material around itself, which has restricted the direction of further outflows. This has caused subsequently ejected material to be expelled in expanding cone shapes perpendicular to the disk. Our view of the Red Rectangle is from the side, at right angles to these cones. COMPLEX STRUCTURE

One of the most unusual celestial bodies in the Milky Way, the Red Rectangle Nebula has a distinctive shape that reflects an extremely complex inner structure.

PLANETARY NEBULA

PLANETARY NEBULA

Cat’s Eye Nebula

Egg Nebula

CATALOG NUMBER

CATALOG NUMBER

NGC 6543

CRL 2688

DISTANCE FROM SUN

DISTANCE FROM SUN

3,000 light-years

TH E M I LKY WAY

MAGNITUDE

3,000 light-years

9.8

MAGNITUDE

14

DRACO

CYGNUS

The Cat’s Eye Nebula is one of the most complex of all planetary nebulae. It is thought that its intricate structures may be produced either by the interactions of a close binary system or by the recurring magnetic activity of a solitary central star. At 3,000 light-years away, it is too far even for the Hubble Space Telescope to resolve its central star. The “eye” of the nebula is estimated to be more than half a light-year in diameter, with a much larger outer halo stretching into the interstellar medium. Although models of planetary nebulae once assumed a continuous outflow of stellar material, this nebula contains concentric rings that are the edges of bubbles of stellar material ejected at intervals. Eleven of these bubbles have been identified, possibly ejected at intervals of 1,500 years. The Cat’s Eye also contains jets of high-speed gas, as well as bow waves created when the gas slammed into slower-moving, previously ejected material.

The Egg Nebula’s central star, which was a red giant until a few hundred years ago, is hidden by a dense cocoon of dust (visible in the image below as the dark band of material across the middle of the nebula). The material shed by the dying star is expanding at the rate of 45,000 mph (72,000 km/h). Distinct arcs of material suggest a varying density throughout the nebula. The light from the central star shines like searchlights through the thinner parts of its cocoon and reflects off dust particles in the outer layers of the nebula.

WAVES AND SYMMETRIES

A composite picture (above) shows emission from nitrogen atoms as red and oxygen atoms as green and blue shades, thus revealing successive waves of expelled stellar material. The nebula’s symmetrical properties are further revealed by a falsecolor image processed to highlight its ring structure (right).

BRIGHT SEARCHLIGHTS

OLD STARS PLANETARY NEBULA

Ant Nebula CATALOG NUMBER

Menzel 3 DISTANCE FROM SUN

4,500 light-years MAGNITUDE

13.8

NORMA

There are two main theories about what has caused the unusual shape of this planetary nebula. Either the central star is a close binary, its interacting gravitational forces shaping

the outflowing gas, or it is a single spinning star whose magnetic field is directing the material it has ejected. The expelled stellar material is traveling at around 2.25 million mph (3.6 million km/h) and impacting into the surrounding slower-moving medium; the lobes of the nebula stretch to a distance of more than 1.5-light-years. Observations of the Ant Nebula may reveal the future of our own star, since its central star appears to be very similar to the Sun. HEAD AND THORAX

Even through a small telescope, this planetary nebula resembles the head and thorax of a common garden ant.

PLANETARY NEBULA

Crescent Nebula CATALOG NUMBER

NGC 6888 DISTANCE FROM SUN

4,700 light-years MAGNITUDE

7.44

CYGNUS

259

(4.5 million km/h). This strong stellar wind expelled material equivalent to the Sun’s mass every 10,000 years, forming a series of dense, concentric shells that are visible today. Typical of emission nebulae, the radiation from the hot central star excites the stellar material, principally hydrogen, causing it to shine in the red part of the spectrum. It is thought that the nebula’s central star will probably explode as a supernova in about 100,000 years.

The central star of the Crescent Nebula is a Wolf–Rayet star. Only about 4.5 million years after its formation (one-thousandth the age of the Sun), this massive star expanded to become a red giant and ejected its outer layers at about 22,000 mph (35,000 km/h). Two hundred thousand years later, the intense radiation from the exposed, hot inner layer of the star began pushing gas away at speeds in excess of 2.8 million mph GASEOUS COCOON

This composite image of the Crescent Nebula shows a compact semicircle of dense material surrounding a pre-supernova star (center). The Crescent spans a distance of about three light-years.

WOLF–RAYET STAR

PLANETARY NEBULA

WR 104

Eskimo Nebula DISTANCE FROM SUN

CATALOG NUMBER

4,800 light-years MAGNITUDE

NGC 2392

13.54

DISTANCE FROM SUN

5,000 light-years

SPECTRAL TYPE

WCvar+

MAGNITUDE

10.11 SAGITTARIUS

GEMINI

The German-born astronomer William Herschel discovered the Eskimo Nebula in 1787, and it has since become a much-loved sight for amateur astronomers. Even through small telescopes, this nebula’s form, suggesting a face ringed by a fur parka hood, is clearly visible.

Hubble Space Telescope images reveal a complex structure, featuring an inner nebula and an outer halo. The inner nebula consists of material ejected from the central star in two elliptical lobes around 10,000 years before the star was as we now see it. Each lobe is about one light-year long and about half a light-year wide, and contains filaments of dense matter. Astronomers think that a ring of dense material around the star’s equator, ejected during its red-giant phase, helped

create the nebula’s “face.” The surrounding “hood” contains unusual orange filaments, each about one light-year long, streaming away from the central star at up to 75,000 mph (120,000 km/h). One explanation for these is that they were created when a fast-moving outflow from the central star impacted into slower-moving, previously ejected material. HOODED NEBULA

In the center of this image, the apparent “face” of the Eskimo consists of one bubble of ejected material lying in front of the other, with the central star visible in the middle.

STELLAR SPIRAL

TH E MI L KY WAY

Like water from a cosmic lawn sprinkler, dust streaming from this rotating star system creates a pinwheel pattern. Since Wolf–Rayet stars are so hot that any dust they emit is usually vaporized, it is surprising that WR 104 has dust streaming away from it in this obvious spiral pattern. One theory is that this is a binary system, with each star emitting a strong stellar wind. Where these winds meet, there is a “shock front” that compresses the outflowing material, creating a denser, slightly cooler environment in which dust can exist. The orbital motion of the two stars then causes the spiral shape.

260

OLD STARS PLANETARY NEBULA

Bug Nebula CATALOG NUMBER

NGC 6302 DISTANCE FROM SUN

4,000 light-years MAGNITUDE

7.1

SCORPIUS

First discovered in 1826 by Scottish astronomer James Dunlop, then rediscovered in the late 19th century by the great American astronomer E. E. Barnard, the Bug Nebula is one of the brightest planetary nebulae. The central star is thought to have an extremely high temperature, and its intense ultrviolet radiation lights up the surrounding stellar material. The star itself is not visible at optical wavelengths because it is hidden by a blanket of dust. It is believed that the central star ejected a ring of dark material about 10,000 years before it was as we see it now, but astronomers cannot explain why it was not destroyed long ago by the star’s ultraviolet emissions. The composition of the surrounding material is also surprising, since it contains carbonates, which usually form when carbon dioxide dissolves in liquid water. Although ice exists in the nebula, along with hydrocarbons and iron, there is no evidence of liquid water. COLORFUL BUG

TH E MI L KY WAY

The Bug Nebula is the ejected outer layers of a dying star that was once about five times the mass of the Sun. Ultraviolet radiation from the intensely hot central star is making the cast-off material glow.

261

TH E M I LKY WAY

262

OLD STARS PLANETARY NEBULA

Calabash Nebula CATALOG NUMBER

OH231.8+4.2 DISTANCE FROM SUN

5,000 light-years MAGNITUDE

9.47

shock waves. Radio observations have revealed an unusually large amount of sulfur in the gas around the star, which may have been produced by the shock waves. This planetary nebula is in the earliest stages of formation and has offered astronomers the chance to observe the kind of processes that led to the creation of more established planetary nebulae elsewhere in the Milky Way.

PLANETARY NEBULA

Gomez’s Hamburger Nebula CATALOG NUMBER

IRAS 18059-3211 DISTANCE FROM SUN

6,500 light-years MAGNITUDE

14.4

PUPPIS

One of the most dynamic planetary nebulae, the Calabash Nebula’s central star is expelling gas at a speed of 435,000 mph (700,000 km/h). The fast-moving material is being channeled into streamers on one side and into a jet on the other. The jet of material appears to be striking denser, slower-moving material, creating

ROTTEN EGG NEBULA

The Calabash Nebula is popularly called the Rotten Egg Nebula because it contains a lot of sulfur, which smells like rotten eggs. The outflows of expelled gas show up bright yellow-orange in the center of this picture.

BLUE SUPERGIANT

Eta Carinae DISTANCE FROM SUN

8,000 light-years MAGNITUDE

6

SPECTRAL TYPE

B0

TH E M I LKY WAY

CARINA

With a mass more than 100 times that of the Sun, this star, which is embedded in an impressive dumbbell of stellar material, is one of the most massive known. Eta Carinae is classified as an eruptive variable star (see pp.282–83), and it experiences two types of irregular eruptions. The first involves a brightening of one to two magnitudes (see pp.232–33) lasting a few years; the second features a briefer, giant eruption that produces a significant increase in total luminosity and the ejection of more than a solar mass of material. Since it was first cataloged by English astronomer Edmond Halley in 1677, Eta Carinae has varied in brightness from eighth magnitude to a magnitude as bright as -1. It is currently around sixth magnitude. In 1841, when it reached a magnitude rivaling that of Sirius, it underwent a giant outburst that produced the two distinctive lobes of outflowing material. These lobes are moving outward at a rate of about 1.2 million mph (2 million km/h). This highly unstable star survived that outburst, but will probably eventually erupt as a supernova.

HOMUNCULUS NEBULA

This false-color optical image shows the Homunculus Nebula surrounding Eta Carinae, which lies at the very center of this image.

EXPLODING DUMBBELL

This false-color image shows the dumbbellshaped clouds of dust and gas first observed being ejected by Eta Carinae about 160 years ago. This is the most luminous star known in the Milky Way, and it could explode in a supernova at any time.

SAGITTARIUS

Discovered in 1985 by the Chilean astronomer Arturo Gomez at the Cerro Tololo Inter-American Observatory in Chile, this dramatic, hamburger-shaped object is a planetary nebula in the making. The central star, obscured by a dark band of dust, is a red giant throwing off its outer layers. Eventually the star’s hot core will be exposed and its ultraviolet radiation will heat up the clouds of dust and gas surrounding it, giving us a full-fledged planetary nebula. It is rare to see nebulae at this early stage of evolution, as this process does not last long. In less than 1,000 years from its presently observed state, the central star will be hot enough to vaporize the dust surrounding it. This nebula is only a small fraction of a light-year across but it will expand as the star continues to eject material.

CELESTIAL SANDWICH

The two “buns”of Gomez’s Hamburger are dust clouds illuminated by the central star. The “meat” of the hamburger is a thick disk of dust surrounding this red giant and obscuring it from our view.

OLD STARS

263

PLANETARY NEBULA

Hourglass Nebula CATALOG NUMBER

MyCn18 DISTANCE FROM SUN

8,000 light-years MAGNITUDE

11.8

MUSCA

The distinctive shape of the stunning Hourglass Nebula has fired much debate over its formation among astronomers. One suggestion is that as the aging, intermediate-mass star started to expand into a red giant, the escaping gas and dust accumulated first as a belt around the star’s equator. As the volume of escaping gas continued to grow, the belt constricted the star’s midsection, forcing the increasingly fast-moving gas into an hourglass shape. Other astronomers argue that the central star has a massive, heavy-element core that produces a strong magnetic field. In this scenario, the shape is a result of the ejected material being constrained by the magnetic field. Yet another suggestion is that the central star is in fact a binary and one of the pair is a white dwarf. A disk of dense material is produced around its middle by the gravitational interactions between the two components, which pinches in the “waist” of the expanding nebula. However, other features of the Hourglass Nebula have so far defied explanation. Astronomers have observed a second hourglass-shaped nebula within the larger one, but, unusually, neither is positioned symmetrically around the central star. Two rings of material seen around the “eye” of the hourglass, perpendicular to one another, are the subjects of continuing studies. EXPLORING SPACE

NEBULA IN ACTION

This revealing picture of the Hourglass Nebula is a composite of three images taken in different wavelengths. The colorful gas rings are nitrogen (red), hydrogen (green), and oxygen (blue).

TH E MI L KY WAY

GAS SHELLS

The beautiful images of the Hourglass Nebula captured by the Hubble Space Telescope have revealed details within planetary nebulae that have revolutionized the study of these elusive but beautiful objects, especially as regards the creation of nonspherical planetary nebulae. These fascinating nebulae are observed in many varied shapes, and an equally large number of hypotheses have been suggested to account for them. The life of a planetary nebula is a mere blink of an eye when compared to the lifetime of a star, but it is a very important stage. When a star is evolving off the main sequence, it loses huge quantities of its material and thus enriches the interstellar medium in elements heavier than helium, which can then be recycled to form other celestial objects.

264

OLD STARS WOLF–RAYET STAR

HD 56925 DISTANCE FROM SUN

15,000 light-years MAGNITUDE

11.4

SPECTRAL TYPE

WN5

CANIS MAJOR

The emission nebula NGC 2359, which has a diameter of around 30 light-years, has been produced by an extremely hot Wolf–Rayet star, visible at its center. This star, designated HD 56925, has a surface temperature of between 54,000°F (30,000°C) and 90,000°F (50,000°C)—six to ten times as hot as the Sun. It is also highly unstable, ejecting stellar material into the interstellar medium at speeds approaching 4.5 million mph (7.2 million km/h). Even though it is a massive star of around 10 solar masses, it is losing about the equivalent of the mass of the Sun every thousand years. With this level of mass loss, Wolf–Rayet stars like HD 56925 are unable to exist in this stage of their life for long, and are therefore rarely observed: only about 550 such stars are known in the Milky Way. Material

THOR’S HELMET

The popular name for the nebula surrounding HD 56925 is Thor’s Helmet, because it looks like a helmet with wings (above). The nebulae surrounding Wolf–Rayet stars are sometimes called bubble nebulae, and HD 56925 lies at the center of the nebula’s main bubble of hot gas (the star is above and to the right of center in the image to the right).

from the star has been ejected in an even, spherical manner, producing a bubble of material. This bubble has been further shaped by interactions with the surrounding interstellar medium. HD 56925 is unusual because it lies at the edge of a dense, warm molecular cloud, and the asymmetrical shape of the outer parts of the surrounding nebula is due to “bow shocks,” produced when fast stellar winds hit denser, static material.

WOLF–RAYET STAR

GRACEFUL SYMMETRY

PLANETARY NEBULA

WR 124

Stingray Nebula DISTANCE FROM SUN

CATALOG NUMBER

15,000 light-years MAGNITUDE

Hen-1357

11.04

SPECTRAL TYPE

DISTANCE FROM SUN

18,000 light-years

WN

MAGNITUDE

STELLAR FIREBALL

WR 124 can be seen as a glowing body at the center of a huge, chaotic fireball. The fiery nebula surrounding the star consists of vast arcs of glowing gas violently expanding outward into space.

TH E M I LKY WAY

10.75

SAGITTARIUS

ARA

With a surface temperature of around 90,000°F (50,000°C), WR 124 is one of the hottest known Wolf–Rayet stars. This massive, unstable star is blowing itself apart—its material is traveling at up to 90,000 mph (150,000 km/h). The observed state of M1-67, the relatively young nebula surrounding WR 124, is only 10,000 years old, and it contains clumps of material with masses about 30 times that of Earth and diameters of 90 billion miles (150 billion km).

The Stingray Nebula is the youngest known planetary nebula. Observations made in the 1970s revealed that the dying star at the center of the nebula was not hot enough to cause the surrounding gases to glow. By the 1990s, further observations had shown that the central star had rapidly heated up as it entered the final stages of its life, causing the nebula to shine. This afforded astronomers a remarkable opportunity to observe the star in an exceedingly brief phase of its evolution. Because of its young age, the Stingray Nebula is one-tenth the size of most planetary nebulae, with a diameter only about 130 times that of the solar system. A ring of ionized oxygen surrounds the central star, and bubbles of gas billow out in opposite directions above and below the ring. Material traveling rapidly outward from the central star has opened holes

CHARLES WOLF AND GEORGES RAYET French astronomers Charles Wolf (1827–1918) and Georges Rayet (1839–1906) co-discovered the type of unusual, hot stars that now bear their name. In 1867, they used the Paris Observatory’s 16-in (40-cm) Foucault telescope to discover three stars whose spectra were dominated by broad emission lines rather than the usual narrow absorption lines (see pp.254–55). Today, over 500 Wolf–Rayet stars are known in our galaxy. Rayet later became Director of the Bordeaux Observatory. GEORGES RAYET

The graceful, symmetrical shape of this very young planetary nebula gives it its popular name. In this enhanced true-color image, the Stingray Nebula’s central star has a companion star just visible above it to the left.

in the ends of the bubbles, allowing streams of gas to escape in opposite directions. On the outer edges of the nebula, the central star’s winds crash into the walls of the gas bubbles, generating shock waves and heat that cause the gas to glow brightly.

OLD STARS

265

RED SUPERGIANT

V838 Monocerotis DISTANCE FROM SUN

20,000 light-years MAGNITUDE

10

SPECTRAL TYPE

K

MONOCEROS

Discovered on January 6, 2002 by an amateur astronomer, V838 Monocerotis is one of the most interesting stars. Its precise nature is not yet fully understood, but astronomers believe its recent evolution has moved it off the main sequence to become a red supergiant. While this phase would usually take hundreds or thousands of years, here it has happened in a matter of months. Its first viewed outburst, in January 2002, was followed a month later by a second in which it brightened from magnitude 15.6 to 6.7 in a single day—an increase of several thousand times. Finally, in March 2002, it brightened from magnitude 9 to 7.5 over just a few days. The energy emitted in the outbursts caused previously ejected shells of material to brighten and become visible. LIGHT ECHOES

Light echoes from recent outbursts illuminate the ghostly shells of ejected material around the enigmatic star V838 Monocerotis (seen glowing red).

BLUE SUPERGIANT

BLUE VARIABLE

Sher 25

Pistol Star DISTANCE FROM SUN

DISTANCE FROM SUN

20,000 light-years MAGNITUDE

25,000 light-years

12.2

SPECTRAL TYPE

LBV

SPECTRAL TYPE

B1.5

SAGITTARIUS

This blue supergiant is poised to explode as a supernova, possibly within the next few thousand years. The prediction of its apparent closeness to death has been based on observations that reveal striking similarities between Sher 25 and Sk-69 202, the progenitor star of the supernova that occurred in the Large Magellanic Cloud in 1987 (now known as SN 1987A, see p.310). Sher 25 lies at the center of a clumpy ring of ejected material, and additional material from the star is escaping perpendicular to this ring. This has caused the ejected stellar material to form an hourglass-shaped nebula with Sher 25 lying at its middle. The ring and nebula are similar to those observed around Sk-69 202 before that blue supergiant exploded. Spectroscopy reveals that the nebula

One of the most luminous stars ever discovered is located at the center of the Pistol Nebula and is known as a luminous blue variable. The Pistol Star emits around 10 million times more light than the Sun, unleashing as much energy in six seconds as the Sun does in one year. It is also one of the most massive stars known, weighing in at 100 times the mass of the Sun. When it originally formed, it may have been up to 200 times the mass of the Sun, but it has ejected at least 10 solar masses of material in giant eruptions. These occurred about 4,000 and 6,000 years before its presently seen state. In the Sun’s position, the star would fill the diameter of Earth’s orbit. Despite its size and luminosity, the star is obscured at visible wavelengths by the ejected material that has formed the pistol-shaped nebula surrounding it.

PENDING SUPERNOVA

The blue supergiant shown boxed in this image is likely to explode as a supernova. The open cluster of bright white stars and the surrounding red nebula are known as NGC 3603.

surrounding Sher 25 is rich in nitrogen, indicating that it has passed through a red supergiant phase, again displaying an evolutionary path similar to that of the star Sk-69 202.

VAST NEBULA

Seen in infrared light, the Pistol Nebula glows a brightly. The nebula is four light-years across and would nearly span the distance from the Sun to Proxima Centauri, the closest star to the solar system.

TH E MI L KY WAY

CARINA

266

STELLAR END POINTS

STELLAR END POINTS THE FORM A STAR TAKES

232–33 Stars 234–37 The life cycles of stars 250–51 Main-sequence stars 254–55 Old stars Variable stars 282–83

in the ultimate stage of its life is called a stellar end point. Such end points include some of the most exotic objects in the Milky Way. The fate of a star is dictated by its mass, with lower-mass stars becoming white dwarfs, and the highest-mass stars becoming black holes, from which not even light can escape. Between these are neutron stars, including spinning pulsars. WHITE DWARFS IN NGC 6791

WHITE DWARFS Once a star has used up all of its fuel through nuclear fusion, the stellar remnant will collapse, as it cannot maintain enough internal pressure to counteract its gravity. Stars of less than about eight solar masses will lose up to 90 percent of their material in stellar winds and by creating planetary nebulae (see p.255). If the remnants of these stars have less than 1.4 solar masses (the Chandrasekhar limit), they will become white dwarfs. White dwarfs are supported by what is known as electron degeneracy pressure, created by the repulsion between electrons in their core material. More massive stars collapse to the smallest diameters and highest densities. The first white dwarf to be discovered, Sirius B (see p.268), has a mass similar to that of the Sun but a radius only twice that of the Earth. Although they have surface temperatures of around 180,000°F (100,000°C) at first, white dwarfs fade over periods of hundreds of millions of years, eventually becoming cold black dwarfs.

TH E M I LKY WAY

SUPERNOVAE Massive stars die spectacularly, blasting their outer layers off into space in type II supernovae explosions. A type I supernova is a type of variable star (see p.283). When a star of more than about ten solar masses reaches the end of its hydrogenburning stage, it will eventually produce an iron core. Initially this core is held up by its internal pressure, but when it reaches a mass greater than 1.4 solar masses (the Chandrasekhar limit), it starts to collapse, forming an extremely dense core almost entirely made of neutrons. Supernova detonation occurs when the outer layers of the star, which have continued to implode, impact on the rigid core and rebound back into space at speeds of up to 45 million mph (70 million km/h). This releases massive amounts of energy, creating a great rise in luminosity that may last DEATH RING for several months, The envelope of Supernova before fading. A 1987A is still expanding outwards supernova remnant at very high velocities, slamming consisting of the debris into interstellar material and creating this ring of glowing gas. will become a nebula.

The faint stars inside the squares in this image are white dwarfs in the globular cluster NGC 6791. Too faint to be seen from the ground, the stars were captured here by the Hubble Space Telescope.

MORGUE OF STARS

Spanning a distance of 900 light-years, this mosaic of X-ray images of the center of the Milky Way reveals hundreds of white-dwarf stars, neutron stars, and black holes. They are all embedded in a hot, incandescent fog of interstellar gas. The supermassive black hole at the center of the Galaxy is located inside the central bright white patch.

shell burning occurs in the star’s large envelope

iron at center

other heavy elements

dense core supergiant star

core contains concentric layers

COLLAPSING STAR

As a massive star collapses, elements heavier than helium are produced in a series of shellburning layers. Elements heavier than iron cannot be produced in this way, and an iron core may collapse to produce a neutron star.

subatomic neutrinos burst from iron core

outer layers of core collapse inward

iron core reaches 1.4 solar masses and starts to collapse

STELLAR END POINTS

NEUTRON STARS Neutron stars are one of the by-products of type II supernovae explosions. During an explosion, the outer layers of a star are blown off, leaving an extremely dense, compact star, consisting predominantly of neutrons with a smaller amount of electrons and protons. Neutron stars have a mass between 0.1 and 3 solar masses. Beyond this limit, a star will collapse further to become a black hole (below). As the neutron star forms, the magnetic field of the parent star becomes concentrated and grows in strength. Similarly, the original rotation of the star increases in speed as the star collapses. Neutron stars are characterized by their strong magnetic fields and rapid rotation. Over time, their rotation slows as they lose energy. However, some neutron stars show a temporary rise in rotation rate, possibly due to tremors, known as starquakes, in their thin, crystalline outer crusts. Neutron stars that emit directed pulses of radiation at regular intervals are known as pulsars (below).

rotation of star

beam of radiation PULSAR OFF

beam aligned with Earth

pulsar on PULSAR ON

beam not aligned with Earth

pulsar off PULSAR OFF

magnetic field

267

beams of radiation

rotation direction

neutron star

HOW PULSARS WORK

Charged particles spiral along the star’s magnetic-field lines and produce a beam of radiation. If the beam passes across the field of Earth, it can be detected as a pulse. Depending on the energy of the radiation, this can be in either the radio or X-ray part of the electromagnetic spectrum.

BLACK HOLES

rotation axis

gravitational well

BLACK HOLE

Here, the gas from a companion star is drawn into a black hole via an accretion disk. When the gas crosses a limit called the event horizon, the gravitational field has become so strong that light cannot escape, and it disappears from view.

NEUTRON STAR

singularity at very center

event horizon

neutron star

The gas drawn from a companion star approaches a neutron star in the same manner. However, when the gas strikes the solid surface of the neutron star, light is emitted and gravitational the star glows. well

light is emitted

TH E M I LK Y WAY

If the remnant of a supernova explosion is greater than about three solar masses, there is no mechanism that can stop it from collapsing. It becomes so small and dense that its resulting gravitational pull is great enough to stop even radiation, including visible light, from escaping. Stellar-mass black holes, as such objects are known, can be detected only by the effect they have on objects around them. Light from far-off objects can be bent around a black hole as it acts as a gravitational lens, while the movement of nearby objects can be affected by a black hole’s strong gravitational field (see pp.42–43). If a stellar-mass black hole is a member of a close binary system (see pp.274–75), the material from its companion star will be pulled toward it by its immense gravity. Matter will not fall directly onto the black hole, due to its rotational motion. Instead it will first be pulled into a accretion disk around the black hole. Matter impacts onto this disk, creating hot spots that can be detected by the radiation they emit. As matter in the disk gradually spirals into the black hole, friction will heat up the gas and radiation is emitted, predominantly in the X-ray part of the electromagnetic spectrum.

magnetic field

268

STELLAR END POINTS

STELLAR END POINTS Stars end their lives in a variety of ways, but many are difficult or impossible to observe. It is thought that unobserved dead stars contribute significantly to the Milky Way’s mysterious missing mass (see pp.22629). Often, black holes and small white dwarfs can be observed only by the effect they have on STAR REMNANT nearby objects, and neutron stars are visible only A rapidly expanding shell of hot gas, Cassiopeia A, shown in gamma-ray wavelengths. However, some stellar in X-ray wavelengths, is end points and their remnants, such as supernovae, here the remnant of a massive star are among the galaxy’s most spectacular sights. that died unnoticed around 1680. NEUTRON STAR

WHITE DWARF

RX J1856.5-3754

Sirius B

CATALOG NUMBER

CATALOG NUMBER

HD 48915 B

1ES 1853-37.9

DISTANCE FROM SUN

DISTANCE FROM SUN

200–400 light-years

8.6 light-years MAGNITUDE

8.5

MAGNITUDE

26

CANIS MAJOR

CORONA AUSTRALIS

This was the first white dwarf to be discovered. First observed in 1862, it was found to be a stellar remnant when its spectrum was analyzed in 1915. Although Sirius A, its companion, is the brightest star in the sky, Sirius B appears brighter in X-ray images (such as the one below). Sirius B’s diameter is only 90 percent that of Earth, but since its mass is equal to that of the Sun, its gravity is 400,000 times that on Earth.

This lone star is the closest known neutron star to Earth. Discussions are ongoing as to its true distance, but estimates vary from 200 to 400 lightyears. There is also much speculation about its age. Some astronomers believe it is an old neutron star emitting X-rays because it is accreting material onto its surface from the surrounding interstellar medium. Others believe it is a young neutron star, emitting X-rays as it cools. It is possible that it formed about 1 million years ago, when a massive star in a close binary system exploded. It is traveling through the interstellar medium at about 240,000 mph (390,000 km/h). RX J1856.5-3754 is moving away from a group of young stars in the constellation of Scorpius. Also moving away from this group of stars is the ultra-hot blue star now

CLOSE COMPANIONS

known as Zeta (ζ) Ophiuchi. It is possible that RX J1856.5-3754 is the remnant of Zeta Ophiuchi’s original binary companion. As the closest neutron star, it is being extensively studied, but its diminutive size makes it difficult for astronomers to obtain conclusive results. Estimates of the diameter of RX J1856.5-3754 vary from 6 miles (10 km) to 20 miles (30 km). This puts it very close to the theoretical limit of how small a neutron star can be, challenging some models of their internal structure. Its X-ray emissions suggest it has a surface temperature of around 1,000,000°F (600,000°C). Its visual magnitude of only 26 means that this star is 100 million times fainter than an object on the limit of nakedeye visibility.

RARE VIEWS

Taken in 1997, a Hubble image (above), offered astronomers an unusual glimpse of a neutron star in visible light. The star’s movement through the interstellar medium has produced a coneshaped nebula, visible in a later image (below).

WHITE DWARF

NEUTRON STAR

NGC 2440 nucleus

Geminga Pulsar

CATALOG NUMBER

CATALOG NUMBER

SN 437

HD 62166

DISTANCE FROM SUN

DISTANCE FROM SUN

3,600 light-years

500 light-years MAGNITUDE

MAGNITUDE

25.5

11

PUPPIS

GEMINI

TH E M I LKY WAY

GAMMA RAY SOURCE

Discovered in 1972, the Geminga Pulsar, a pulsating neutron star, is the second-brightest source of high-energy gamma rays known in the Milky Way. Its name is a contraction of “Gemini gamma-ray source”; it is also an expression, in the Milanese dialect, meaning “It’s not there,” because only recently has this object been observed in wavelengths other than gamma rays. Variations in the pulsar’s period of luminosity (see pp.280–81) have suggested that it may have a

The Geminga Pulsar shines bright in an image taken through a gamma-ray telescope. Gamma-ray photons are blocked from Earth's surface by the atmosphere.

companion planet, but they may also be due to irregularities in the star’s rotation. Geminga is believed to be the remnant of a supernova that took place about 300,000 years earlier in the star’s life. It is traveling through space at almost 15,000 mph (25,000 km/h), at the head of a shock wave 2 billion miles (3.2 billion km) long.

The central star of the planetary nebula NGC 2440 has one of the highest surface temperatures of all known white dwarfs. This stellar remnant has a surface temperature of around 360,000°F (200,000°C)—40 times hotter than that of the Sun. This also makes it intrinsically very bright, with a luminosity more than 250 times that of the Sun. The complex structure of the surrounding nebula has led some astronomers to believe that there have been periodic ejections of material

INNER LIGHT

Energy from the extremely hot surface of NGC 2440’s central white dwarf makes this beautiful and delicate-looking planetary nebula fluoresce.

from the dying central star. The structure of the nebula also suggests that the material was ejected in various directions during each episode.

STELLAR END POINTS SUPERNOVA REMNANT

The Cygnus Loop CATALOG NUMBER

NGC 6960/95 DISTANCE FROM SUN

2,600 light-years MAGNITUDE

11

the Veil Nebula, and, because it is so large, the Cygnus Loop has been cataloged using many different reference numbers. The supernova remnant is some 80 light-years long and sprawls 3.5 degrees across the sky— about seven full moons across. It shines in the light generated by shock waves

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GLOWING FILAMENTS

Filaments of shocked interstellar gas glow in the light emitted by excited hydrogen atoms. This side-on view shows a small portion of the Cygnus Loop moving upward at about 380,000 mph (612,000 km/h).

CYGNUS

COLORFUL GASES

The Cygnus Loop is the remnant of a dying star that blew itself up in a supernova. Estimates of how long ago in the star's lifetime this event occurred vary from 5,000 to 15,000 years. The most prominent parts of the nebula seen in visible light are often called

produced as stellar material from the supernova hits material in the interstellar medium. Observations of this stellar laboratory have revealed an inconsistent composition and structure of the interstellar medium as well as that of the supernova remnant.

This composite image of a section of the Cygnus Loop reveals the presence of different kinds of atoms excited by shock waves: oxygen (blue), sulfur (red), and hydrogen (green).

SUPERNOVA REMNANT

Vela Supernova

EXPANDING SHELL

This optical photograph of the Vela Supernova Remnant shows part of its spherical, nebulous shell expanding out into the interstellar medium.

CATALOG NUMBER

NGC 2736 DISTANCE FROM SUN

6,000 light-years MAGNITUDE

12

VELA

DYNAMIC JET

This series of false-color X-ray images reveals a flailing jet of high-energy particles, half a light-year long, emitted by the Vela Pulsar. These images are part of a series of 13 images made over a period of two and a half years.

NOVEMBER 30, 2000

DECEMBER 11, 2001

DECEMBER 29, 2001

APRIL 3, 2002

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The Vela Supernova Remnant is the brightest object in the sky at gamma-ray wavelengths. It is estimated that the star that produced it exploded between 5,000 and 11,000 years previously, and that its final explosion would have rivaled the Moon as the brightest object in the night sky. The star that died has become a pulsar, a rapidly spinning neutron star, which rotates about 11 times each second. The Vela Pulsar is about 12 miles (19 km) in diameter and was only the second pulsar to be discovered optically, the optical flashes being observed in 1977. As with other pulsars, the rotation rate of the Vela Pulsar is gradually slowing down. Since 1967, it has suffered several brief glitches where its rotation rate has temporarily increased before continuing to slow.

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CONSPICUOUS REMNANT

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The still-expanding Crab Nebula supernova remnant is seen here in a composite image showing wavelengths of visible light (red and yellow), infrared (purple), and X-ray (blue).

STELLAR END POINTS

271

SUPERNOVA REMNANT

Crab Nebula CATALOG NUMBERS

M1, NGC 1952 DISTANCE FROM SUN

6,500 light-years MAGNITUDE

8.4

TAURUS

TH E M I LKY WAY

In the summer of 1054, during the Sung dynasty, Chinese astronomers recorded that a star, in the present-day constellation Taurus, had suddenly become as bright as the full moon. FALSE-COLOR MAP They described it as a reddish-white This false-color optical image maps the “guest star,” and observed it over a intensity of light emitted from the Crab period of two years as it slowly faded. Nebula. The brightest regions are shown in Their records show it was visible in red, followed by yellow, green, then blue, to the coolest regions represented in gray. daylight for more than three weeks. They had witnessed a supernova, and The pulsar (known as PSR 0531 +21) the stellar material flung off in this cataclysmic explosion now shines as the is observable optically and in radio, X-ray, and gamma-ray wavelengths wispy filaments of the Crab Nebula. because the beams it This nebula is the generates happen to very first object, and be directed toward the only supernova Earth during part remnant, to be listed of its revolution. It by Charles Messier was discovered in (see p.73) in his 1967, but had been famous catalog. known previously as The nebula is easily a powerful emitter visible in binoculars of radio waves and and small telescopes. X-rays. It was the It spans a distance of first pulsar to be about 10 light-years identified optically with a magnitude of and is of 16th between 8 and 9. RADIO MAP magnitude. It is The remains of A false-color radio map of the Crab estimated to have the original star have Nebula shows the glowing emission a diameter of only become a spinning of electrons spiraling in the central neutron star, a pulsar, pulsar's strong magnetic fields. These about 6 miles (10-km) but a mass rotating at about are created by the pulsar rotating greater than the 30-times per second. about 30 times per second. Sun’s. Its energy output is more than 750,000 times that of the Sun. Its rotation is decreasing by about 36.4 nanoseconds every day, which means that over 2,500 years from its presently observed state, its rotation period will have doubled (see pp.282–83). The loss of rotational energy is being translated into energy, which is heating the surrounding Crab Nebula. As the most easily observable supernova remnant, the Crab Nebula has been extensively studied. Detailed observations show that the material within the central portion of the nebula changes within a time scale of only a few weeks. Wispy features, each about a light-year across, have been observed streaming away from the pulsar at half the speed of light. These are created by an equatorial wind emitted by the pulsar (see left). They brighten and then fade as they move away from the pulsar and expand out into the main body of the nebula. The most dynamic feature PULSAR CLOSEUP within the center is the point where This X-ray image of the central region one of the polar jets from the pulsar of the Crab Nebula shows its pulsar cannons into the surrounding as a white dot near the center. Jets of previously ejected material, forming matter stream away from the poles of a shock front. The shape and position the rapidly rotating pulsar, and energetic of this feature have been observed to particles from its equator plow into change over very short time scales. the surrounding nebula.

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STELLAR END POINTS NEUTRON STAR

BLACK HOLE

BLACK HOLE

PSR B1620-26

Cygnus X-1

GRO J1655-40

CATALOG NUMBER

CATALOG NUMBER

PSR B1620-26

V* V1033 Sco

HDE 226868

DISTANCE FROM SUN

DISTANCE FROM SUN

DISTANCE FROM SUN

7,000 light-years MAGNITUDE

CATALOG NUMBER

8,200 light-years

6,000–9,000 light-years

21.3

MAGNITUDE

17

MAGNITUDE

8.95

SCORPIUS

SCORPIUS

CYGNUS

Situated in the globular cluster M4, the pulsar PSR B1620-26 rotates more than 90 times per second and has a mass of about 1.3 solar masses. It has a white-dwarf companion (boxed in the image below). A third companion is thought to be a planet twice the mass of Jupiter (see pp.296– 99). This planet is named Methuselah, as it may be up to 13 billion years old.

Discovered in 1994, as a source of unusual X-ray emissions, this black hole produces outbursts in which jets of material are ejected at speeds close to the speed of light. In addition to this, the gas surrounding GRO J1655-40 displays an unusual flicker (at a rate of 450 times per second) that can be explained as a rapidly rotating black hole. This is only the second object of this type to have been found in the Milky Way. It has been suggested that a subgiant star is orbiting the black hole, which is six to seven times the mass of the Sun. Their orbits are thought to be inclined at 70 degrees to each other, causing partial eclipses. Mass has been pulled off the subgiant star by the gravitational interaction from the black hole and formed a disk of material around the system. This system has been dubbed a mini-quasar because of its similarity to active galactic nuclei (AGNs) (see pp.306-309).

This X-ray source was one of the first to be discovered, and is one of the strongest X-ray sources in the sky. The X-ray emissions from Cygnus X-1 flicker at a rate of 1,000 times per second. In 1971, astronomers observed a radio source at the same

WHITE-DWARF COMPANION

position in the sky and also identified an optical object, the blue supergiant star HDE 226868. This star has a mass of 20–30 solar masses and is visible through binoculars. It is in a 5.6-day orbit with Cygnus X-1, which has a mass of about six solar masses. Further observations have shown that the black hole is slowly pulling material from its companion supergiant and increasing its own mass. Cygnus X-1 was the first object to be identified as a stellar-mass black hole. ELUSIVE BLACK HOLE

Cygnus X-1 is located close to the red emission nebula Sh2-101, within the rich Cygnus Star Cloud (below). A negative optical image helps to pinpoint its companion, HDE 226868.

RADIO ENERGY

SUPERNOVA

Tycho’s Supernova CATALOG NUMBER

SN 1572

A radio image of Tycho’s Supernova shows areas of low (red), medium (green), and high (blue) energy. A shock wave produced by the expanding debris is shown by the pale blue circular arcs on the outer rim.

DISTANCE FROM SUN

7,500 light-years MAXIMUM MAGNITUDE

-3.5 CASSIOPEIA

In 1572, Tycho Brahe (see panel, below) observed a supernova in the constellation Cassiopeia and recorded its brightness changes in exceptional detail. It brightened to around -3.5—

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TYCHO BRAHE The leading astronomer of his day, Tycho Brahe (1546-1601) founded a great observatory in Uraniborg, Denmark, and spent years making detailed observations of planetary movements and the positions of the stars. Johannes Kepler became his assistant, and Tycho’s work was to give the empirical basis for Kepler’s laws of planetary motion.

as bright in the sky as Venus—before fading over a period of about six months. This brilliant new object was to help astronomers reject the idea that the heavens were immutable. The remnant from this supernova is still expanding and has a current diameter estimated at nearly 20 light-years. Its stellar material is estimated to be traveling at 14.5–18 million mph (21.5–27 million km/h), which is the highest expansion rate observed for any supernova remnant. No strong central point source is detected in the remnant, which suggests that Tycho was a Type Ia supernova. The model for this type of supernova is the destruction of a white dwarf when infalling matter from a companion star increases its mass beyond the Chandrasekhar limit (see pp.266-67). This concurs with the recent discovery of what astronomers think is the burned-out star from the heart of the supernova. The star was discovered because it is moving at three times the speed of other objects in the region. At the edge of the remnant is a shock wave heating the stellar material to 36 million °F (20 million °C); the interior gas is much cooler, at 18 million °F (10 million °C).

DEBRIS CLOUD

A Chandra Telescope X-ray image shows a false-color, wide-field view of the region around Tycho’s Supernova. The image is cut off at the bottom because the southernmost region of the remnant fell outside the field of view of the Chandra camera.

STELLAR END POINTS

273

VISIBLE WISPS

SUPERNOVA

In this optical image, the supernova remnant appears as a faint ring of gas filaments. Having been expelled by the original explosion, this stellar material becomes heated and glows as it plows through the interstellar medium.

Kepler’s Star CATALOG NUMBER

SN 1604 DISTANCE FROM SUN

13,000 light-years MAXIMUM MAGNITUDE

-2.5 OPHIUCHUS

The last supernova explosion in the Milky Way to be observed is named after Johannes Kepler, who witnessed it in October 1604. This previously unremarkable star reached a magnitude of -2.5 and remained visible to the naked eye for more than a year. Its position is now marked by a strong radio source and, in optical light, by a wispy supernova remnant, generally known as Kepler’s Star. Observations have revealed that the supernova remnant has a diameter of about 14 light-years and that the material within it is expanding at 4.5 million mph (7.2 million km/h). Kepler’s Star has been imaged by three of NASA’s great observatories: the Hubble Space Telescope, the Spitzer Space Telescope, and the Chandra X-Ray Observatory.

A combination of these images (right) has highlighted the remnant’s distinct features. It shows an expanding bubble of iron-rich material surrounded by a shock wave, created as ejected material slams into the interstellar medium. This shock wave, shown in yellow, can also be seen optically (above). The red color is produced by microscopic dust particles, which have been heated by the shock wave. The blue and green regions represent locations of hot gas: blue indicates high-energy X-rays and the highest temperatures; green represents lower-energy X-rays. COMBINED IMAGE

A composite picture made using images from three separate telescopes offers a view ranging from X-ray through to infrared.

BLACK HOLE

SUPERNOVA

MACHO 96

Cassiopeia A

CATALOG NUMBER

CATALOG NUMBER

SN 1680

MACHO 96

DISTANCE FROM SUN

DISTANCE FROM SUN

Up to 100,000 light-years

10,000 light-years MAXIMUM MAGNITUDE

6

SAGITTARIUS

CASSIOPEIA

An intense radio source, Cassiopeia A is the remnant of a supernova explosion that occurred in the middle of the 17th century. The fact that no reports of the original explosion have been found suggests it may have been of unusually low optical luminosity. Today, Cassiopeia A is the strongest discrete low-frequency radio source in the sky (after the Sun). The radio waves are produced by electrons spiraling in a strong magnetic field. Cassiopeia A is about 10 light-years in diameter and is expanding at a rate of about 5 million mph (8 million km/h).

COLOR-CODED IMAGE

This Hubble Space Telescope image of Cassiopeia A’s cooling filaments and knots has been color-coded to help astronomers understand the chemical processes involved in the recycling of stellar material.

SHOCK WAVES

This false-color X-ray image clearly shows (in green) the edges of Cassiopeia A’s expanding shock wave. The tiny white dot at the center is the neutron star created by the supernova explosion.

Although we cannot see black holes, we can detect their presence by measuring their effects on objects around them. The existence of the black hole named MACHO 96 is inferred from the observed brightening of a star lying beyond the black hole caused by a process called lensing (see p.327). Through this process, the black hole’s mass bends the light from the star in the same way as a lens does. The distant star is temporarily magnified, and we see a brief and subtle brightening in the star’s output. The dark lensing object MACHO 96

Two ground-based images of a crowded star field (above) show the slight brightening of a star caused by the gravitational lensing of the passing MACHO 96. A Hubble Space Telescope image of the same area (right) resolves the star and allows its true brightness to be determined.

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PASSING BLACK HOLE

has been calculated to be a six-solarmass black hole that is moving independently among other stars. The chances of observing such a lensing event are estimated to be extremely slim. Therefore astronomers monitor millions of stars every night, using computers to analyze the brightness of the stellar images captured by advanced camera systems. So far, fewer than 20-events have been detected looking toward the Large Magellanic Cloud, a nearby galaxy (see pp.310-11). MACHO 96 was initially detected by the MACHO Alert System in 1996 and subsequently monitored by the Global Microlensing Alert Network. However, it was only by studying images taken by the Hubble Space Telescope that astronomers could identify the lensed star and determine its true brightness (see below). Observations have suggested that the distant star may be a close binary system, but astronomers are still debating whether the lensing object lies in the Milky Way’s Galactic Halo or in the Large Magellanic Cloud.

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MULTIPLE STARS

MULTIPLE STARS A MULTIPLE STAR IS A SYSTEM

232–33 Stars 238–39 Star formation 268–69 Stellar end points Variable stars 282–83 Star clusters 288–89 Extra-solar planets 296–99

of two or more stars bound together by gravity. Systems with two stars are called binary or double stars. Although at first sight only a few stars appear to be multiple, it is estimated that they may account for over 60 percent of stars in the Milky Way. Binary stars orbit each other at a great variety of distances, with orbital periods ranging from a few hours to millions of years. Multiple stars allow astronomers to determine stellar masses and diameters and give them insights into stellar evolution.

BINARIES AND BEYOND Although there are many millions of multiple systems within the Milky Way, not all of them consist of just two stars in mutual orbit. What may appear to be a double or binary star can often reveal itself to be a more complex system of three or more stars. A simple binary system consists of two stars orbiting each other. If the stars are of similar mass, they orbit around a common center of gravity, located between them. If one of the stars is much more massive than the other, the common center of gravity may be located inside the massive star. The more massive star then merely exhibits a wobble, while the secondary star appears to take on all the orbital motion. However, multiple systems may have BRIGHT BINARY One of the brightest stars in our a greater orbital complexity, with multiple centers of sky, Alpha (α) Centauri is also a gravity. For example, a quadruple system may have two striking double star, with two pairs of stars orbiting each other, while the individual sunlike components that orbit stars within the pair are also in mutual orbit. each other in just under 80 years. center of gravity

center of gravity

DETECTING BINARIES

center of gravity

EQUAL MASS

UNEQUAL MASS

DOUBLE BINARY

In binaries with stars of equal mass, the common center of gravity lies midway between the stars.

If one star in a binary system is more massive, the center of gravity lies closer to the higher-mass star.

In a double binary system, each star orbits its companion, and the two pairs orbit a single center of gravity.

star dims when brighter star is eclipsed

LUMINOSITY

slight dimming when fainter star is eclipsed

period for one orbit

light curve is steady, with sudden changes during eclipses

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TIME

Astronomers detect binary stars in a variety of ways. Line-of-sight binaries consist of stars that appear in the sky to be related but, in fact, are not physically associated. These are usually identified by determining the distances to the individual stars. Visual binaries are detected when the naked eye or magnification splits the stars and shows each one separately. Measurements of each star’s position over time allow astronomers to compute their orbit. Although they cannot be separated with a telescope, astrometric binaries are detected when an unseen companion causes a star to wobble periodically through its gravitational influence. Spectroscopy can also be used to identify binary stars, when a star’s spectrum appears doubled up and actually consists of the combined spectrums of two stars orbiting each other. ECLIPSING BINARIES These systems are known as spectroscopic Eclipsing binary stars are detected binaries. The apparent magnitude of a by variations in a star’s magnitude. binary star may show periodic fluctuations, These variations occur when stars caused by the stars eclipsing each other. periodically pass in front of each Such stars are known as eclipsing binaries. other during orbit.

CO-EVOLUTION

EXTREME BINARIES

Like all stars, those within a multiple system evolve. A binary system can start out as two main-sequence stars with a mutual, regular orbit and predictable eclipses. However, over millions of years, the stars progress through their evolutionary stages, which may result in a binary system with two stars of completely different characteristics. One example is the Sirius system (see p.252). The evolution of one star within a system can change the behavior of the whole system. For example, should a star expand and become a red giant, the expansion can bring the evolving star to interact with its companion star. This leads to mass transfer, and if the companion has itself evolved into a white dwarf, the result can be a cataclysmic material is being explosion (see p.283). Stellar evolution transferred can thus convert a stable binary system continuously into a scene of immense violence.

Many binary systems exhibit perfectly regular behavior, with the stars orbiting each other for millions of years with no dramatic changes. However, other binary systems, particularly those that have undergone evolutionary changes, may exhibit much more extreme behavior. One example is a contact binary system, in which the two stars are touching each other. In this case, a massive star transfers material to the secondary star at a faster rate than the secondary star can absorb. This results in the material forming a common envelope that surrounds both stars. The envelope then creates frictional drag, causing the stars’ orbital periods to change. In this way, a binary system with a wide separation and an orbital period of about a decade may be converted into a rapid system with the stars orbiting in a matter of hours. Other binary systems seem to operate at the extremes of physics. The discovery in 1974 of a binary pulsar system opened up a new field of observation in gravitational physics. A strong source of gravitational waves, binary pulsars are very regular and precise systems.

INTERACTING BINARIES stream of gas swollen star taken from loses mass companion

The stars in some binary systems are located so close together that material can pass between them. Here, one of the stars has swollen and is spilling gas onto the other.

275

One of the most famous multiple star systems, Theta (θ) Orionis, or the Trapezium (top left of image), is the middle star in the sword of Orion (see pp.390–91). Its four brightest stars are easily separated with a telescope, but it is made up of a total of at least 10 stars.

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HUB OF STARS

276

MULTIPLE STARS Most of the stars in the Milky Way are members of either binary or multiple systems—single stars like the Sun are more unusual. These systems vary from distant pairs in slow, centuries-long orbits around a common center of mass to tightly bound groups that orbit each other in days and may even distort each other’s shape. Most multiples are so close together that we know TRAPEZIUM The multiple star known as about them only from their spectra. They also vary Theta Orionis, or the Trapezium, widely in size and color—stars of any age and type is a system containing at least can be members of a multiple star system. ten individual stars. TRIPLE STAR

SEXTUPLE SYSTEM

Castor

Omicron Eridani DISTANCE FROM SUN

DISTANCE FROM SUN

16 light-years MAGNITUDE

51 light-years

9.5

SPECTRAL TYPE

MAGNITUDE

DA

1.6

SPECTRAL TYPE

A2

Castor A consists of two stars in a very close 9.2-day orbit, while Castor B’s components orbit each other in a rapid 2.9 days. The faint Castor C star is also a double—a pair of faint reddwarf stars orbiting each other with a period of only 20 hours. Castor is therefore a sextuplet star, a doubledouble-double. DOUBLE-DOUBLE-DOUBLE

ERIDANUS

GEMINI

Originally Omicron (ο) Eridani was classed as a double star, Omicron-1 Eridani and Omicron-2 Eridani. Nineteenth-century observations revealed that the system is actually three stars, now called 40 Eridani A, B, and C. A is a main sequence orange-red dwarf, and C is a faint red dwarf. However, it is 40 Eridani B that is the gem. This young white dwarf is the brightest white dwarf visible through a small telescope.

Easily visible to the naked eye, Castor appears to be an ordinary A-type star. However, a telescope reveals that Castor is in fact a pair of bright A-type stars, Castor A and Castor B, with a fainter third companion, Castor C. Spectrographic analysis shows that both the A and B components of Castor are themselves double stars.

Castor (boxed) and its neighbor Pollux are the two brightest stars in Gemini (below). Only when viewed through a telescope are the individual stars, Castor A and Castor B, separated (right).

TRIPLE SYSTEM

QUADRUPLE STAR

QUADRUPLE STAR

Mizar and Alcor

Algol

Epsilon Lyrae

DISTANCE FROM SUN

DISTANCE FROM SUN

81 light-years

93 light-years

MAGNITUDE

2

SPECTRAL TYPE

TH E M I LKY WAY

QUADRUPLE STAR

MAGNITUDE

A2

DISTANCE FROM SUN

160 light-years

2.1

SPECTRAL TYPE

MAGNITUDE

B8

3.9

SPECTRAL TYPE

A4

URSA MAJOR

PERSEUS

LYRA

Although Mizar and Alcor are a famous naked-eye double, easily visible in the handle of the Big Dipper and known since ancient times as the horse and rider, it is still unknown whether or not they are a genuine double. Mizar itself is a double star— the first double star to be discovered. Spectrography reveals, however, that Mizar is a double-double star—that is, two double stars in orbit around each other.

Algol, or Beta (β) Persei, appears to the naked eye as a single star. However, exactly every 2.867 days, the star’s brightness drops by 70 percent for a few hours—a variation that was discovered as early as 1667. This variation is caused by Algol’s being eclipsed by a faint giant star Algol B, which is larger than the bright primary Algol A.

FAMOUS DOUBLE

ECLIPSING BINARY

Epsilon (ε) Lyrae is visible as a double star on a clear, dark night, but closer observation reveals that, in fact, each star is itself a double. Unlike other double-double systems, Epsilon Lyrae is within reach of amateur astronomers—its four component stars can each be seen through a telescope, and spectroscopy is not needed to detect their presence (see p.274). The two bright stars visible to the naked eye, Epsilon-1 and Epsilon-2, are widely separated, with an orbital period of millions of years. The components of each pair orbit

ISOLATED PAIRS

This double-double system is easily separated into its four components through a telescope. Although the stars in each pair are strongly bound to one another, the link between the pairs is tenuous.

much more closely, with a period of about 1,000 years. Epsilon-1 and Epsilon-2 are so far apart they are hardly bound by gravity at all, and eventually Epsilon Lyrae will become two separate star systems.

MULTIPLE STARS DOUBLE STAR

DOUBLE STAR

Zeta Boötis

QUADRUPLE STAR

Izar

Almach

DISTANCE FROM SUN

DISTANCE FROM SUN

180 light-years

210 light-years

MAGNITUDE

3.8

SPECTRAL TYPE

MAGNITUDE

A3

277

DISTANCE FROM SUN

355 light-years

2.4

SPECTRAL TYPE

MAGNITUDE

A0

2.3

SPECTRAL TYPE

K3 ALMACH

BOOTES

BOOTES

ANDROMEDA

Zeta (ζ) Boötis would appear to be a standard double star—two A-type stars orbiting each other with a period of about 123 years. However, anomalies in calculations of its mass have suggested that there is something strange about the Zeta Boötis system. The answer lies in a highly elongated orbit, in which the stars range from 130–5,900 million miles (210–9,500 million km) apart. At their closest, they are almost as close as the Sun and Earth, and no telescope can visually split them. The Zeta Boötis system is about 40 times as luminous as the Sun, with about four times its mass, and has a temperature of about 15,700°F (8,700°C).

Izar, or Epsilon (ε) Boötis, is one of the best double stars in the sky. Its stars exhibit a striking color contrast— an orange giant close to a white dwarf—and it was given the name Pulcherrima, “most beautiful,” by its discoverer, German-born Friedrich Struve. The dwarf star is about twice the size of the Sun, while the orange giant is about 34 times the size. The dwarf and giant orbit each other with a period of more than 1,000 years. This double star is not particularly astronomically unusual, but is well known to amateur astronomers for its visual splendor.

Almach, or Gamma (γ) Andromedae, is well known to amateur astronomers as being a fine example of a double star with contrasting colors. The brighter star is yellow-orange, and the fainter star is blue, and through a telescope the two colors enhance

DOUBLE STAR

M40 DISTANCE FROM SUN

1,900 and 550 light-years MAGNITUDE

DWARF AND GIANT

8.4

SPECTRAL TYPE

G0

URSA MAJOR

ENHANCED IMAGES

When the components of Zeta Boötis are at their farthest apart, image-processing software can be used to separate them, and even split their spectra.

QUADRUPLE STAR

Alcyone DISTANCE FROM SUN

368 light-years MAGNITUDE

2.9

SPECTRAL TYPE

TAURUS

B7

Some multiple stars are famous for their beauty, others for the dramatic astrophysics played out within the system. In the case of M40, neither applies. When compiling his wellknown catalog of star clusters and nebulae, Charles Messier (see p.73) Alcyone, one of the sisters of the Pleiades (see p.291), is a bright giant star of spectral type B that shines about 1,500 times more brightly than the Sun. Orbiting around Alcyone are three stars forming a compact system: 24 Tau (magnitude 6.3) and V647 Tau (magnitude 8.3) are both A-type stars, while HD 23608 (magnitude 8.7) is an F-type star. V647 Tau is a variable of the Delta Scuti type. The system of three stars orbits Alcyone at a distance

each other. The brighter star is a giant K-type star, while the fainter star is itself a double star, consisting of two hot, white main-sequence stars in a mutual orbit, with a period of about 60 years. It is difficult to split these two stars visually, but spectroscopic analysis reveals that one of them is also a double star in turn, making Almach a quadruple system.

of a few billion miles. Alcyone is unusual in that it rotates at high speed. This has caused it to throw gas off at its equator, which forms a light-emitting disk. It is classified as a Be star (see p.285), similar to Gamma (γ) Cassiopeiae.

OPTICAL PAIR

observed two stars close to each other in the night sky and erroneously included them. The two stars are nothing more than an optical double—that is, they happen to lie on the same line of sight. Modern distance measurements have shown that they are not truly associated with each other. M40 is therefore a double that achieves fame through error. SEASONAL SIGNAL

Alcyone is the brightest star in the Pleiades Cluster (see p.291). Its appearance over the eastern horizon signals the start of fall in the Northern Hemisphere.

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TH E M I LKY WAY

278

NORTH POLE STAR

Polaris may appear motionless, but a long-exposure photograph reveals it is slightly offset from the celestial pole. Polaris’s movement is marked by the bright arc just left of center.

MULTIPLE STARS

279

DOUBLE STAR

Polaris DISTANCE FROM SUN

430 light-years MAGNITUDE

2

SPECTRAL TYPE

F7

URSA MINOR

Polaris is famous as the current north Pole Star, and consequently is known to every observer of the northern sky (see panel, below). However, it is also an interesting system in terms of its component stars. Polaris is a double star, consisting of Polaris A, a supergiant, and Polaris B, a mainsequence star. The two stars can be separated through a modest amateur telescope, and Polaris B was first detected by William Herschel in 1780. The distance between them has been estimated at more than 190 billion miles (300 billion km). Polaris A is more than 1,800 times more luminous than the Sun, and is also a Cepheid variable with a period of just under four days (see p.282). The radial velocity, or line-of-sight motion, of Polaris has been accurately measured (see p.70), and found to vary regularly with a period of 30.5 years. This indicates that Polaris is also an astrometric binary—that is, the presence of an unseen companion is detected by the movement it induces in the primary star (see p.274). The companion, which was seen for the first time in a Hubble Space Telescope image in 2005, orbits Polaris with a 30.5- year period, but is so faint that it has no effect on Polaris’s spectrum.

DISTINCTIVE STAR

One of the best-known stars in the northern sky, Polaris lies just away from the celestial pole, in the tail of Ursa Minor, the Little Bear. This telescope view reveals the faint companion, Polaris B, but a second smaller companion remains invisible. EXPLORING SPACE

CELESTIAL SIGNPOST

IN THE LITTLE BEAR’S TAIL

In Arabic mythology, Polaris was an evil star who killed the great warrior of the sky. The dead warrior was said to lie in the tail of the little bear, a constellation that also represented a funeral bier.

TH E M I LKY WAY

Polaris has long been regarded as the most important star in the northern sky. Since it is located almost directly overhead at the north pole, it has long been used, just like a compass, to locate north. By calculating the relative angle of Polaris above the horizon, travelers by land and sea have also used Polaris to establish approximate latitudinal positions on the Earth’s surface. The status accorded to Polaris by disparate cultures is reflected in their myths. In Norse mythology, Polaris was the jewel on the head of the spike that the gods stuck through the universe. The Mongols called Polaris the Golden Peg that held the world together. In ancient China, Polaris was known as Tou Mu, the goddess of the North Star.

280

MULTIPLE STARS DOUBLE STAR

15 Monocerotis DISTANCE FROM SUN

1,020 light-years MAGNITUDE

4.7

SPECTRAL TYPE

O7

MONOCEROS

TH E M I LKY WAY

15 Monocerotis (15 Mon), also known as S Monocerotis, is an Otype binary system located within the open cluster NGC 2264. It is a blue supergiant star—young, massive, and about 8,500 times more luminous than the Sun. It is also a variable star, exhibiting a small (0.4 magnitude) change in brightness. 15 Mon is responsible for illuminating the Cone Nebula (see p.242), and consequently is an easy target for amateur astronomers. 15 Mon is an astrometric and spectroscopic binary—that is, its companion star is detected through observations of the motion of 15 Mon, and also through spectroscopic analysis of 15 Mon’s starlight (see p.274). The companion orbits 15 Mon with a period of 24 years, and recent studies using the Hubble Space Telescope show that the closest approach between the stars occurred in 1996. It has been suggested that 15 Mon is a multiple system, with three other bright giants nearby, but there is no evidence that the other giants are associated with 15 Mon.

BRILLIANT ILLUMINATION

Even the most powerful telescopes cannot separate the two stars of 15 Monocerotis visually. The brilliant blue star lights up the emission nebula that surrounds it.

BRIGHTEST STAR

The brightest star in the open star cluster NGC 2264, 15 Monocerotis sits in close visual proximity to the Cone Nebula (see p.242).

MULTIPLE STARS TRIPLE STAR

TRIPLE STAR

Beta Monocerotis

Rigel

DISTANCE FROM SUN

DISTANCE FROM SUN

700 light-years

860 light-years

MAGNITUDE

5.4

SPECTRAL TYPE

MAGNITUDE

B2

0.1

SPECTRAL TYPE

B8

double star itself. It consists of two faint B-type main-sequence stars, Rigel B and Rigel C, separated by about 2.5 billion miles (4 billion km) and orbiting each other in an almost circular orbit. By contrast, the separation between the bright supergiant and the BC pair is over 190 billion miles (300 billion km). BRILLIANT GIANT

MONOCEROS

ORION

Beta (β) Monocerotis is a triple star system, with components A, B, and C. The BC pair orbits each other with a period of about 4,000 years, and A orbits the BC pair with a period of about 14,000 years. The system is unusual because the three stars are so similar. All are hot, blue-white B-type stars, each more than 1,000 times as luminous and six times as massive as the Sun. All three stars also exhibit the same rotation speed and have circumstellar disks.

Rigel is a blue supergiant star shining 40,000 times more brightly than the Sun and has a faint close companion, Rigel B. The luminosity of Rigel makes observation of the companion difficult. Rigel B has been discovered to be a

Rigel is the brightest star in the constellation Orion and the 7th-brightest star in the night sky. Rigel B and C, its companion stars, are obscured by Rigel’s great luminosity.

COMPUTER-ENHANCED OPTICAL IMAGE

QUINTUPLE STAR

Theta Orionis

DISTANCE FROM SUN

DISTANCE FROM SUN

1,150 light-years

1,800 light-years

MAGNITUDE

3.8

SPECTRAL TYPE

DOUBLE STAR

Beta Lyrae DISTANCE FROM SUN

880 light-years MAGNITUDE

3.5

SPECTRAL TYPE

MAGNITUDE

O9

4.7

SPECTRAL TYPE

B

LYRA

Beta (β) Lyrae, or Sheliak, is the prototype of a class of eclipsing binary stars known as Beta Lyrae stars or EB variables (see p.274). The brightness of the system varies by about one magnitude every 12 days 22 hours and is easily visible to the naked eye. Beta Lyrae’s component stars are contact binaries, and are so close together that they are greatly distorted by their mutual attraction. Material pouring out of the stars is forming a thick accretion disk.

ORION

Sigma (σ) Orionis is a quintuple system, containing four bright, easily visible stars and one fainter component, with the brightest being a close double. The two main stars, A and B, are more than 30,000 times as luminous as the Sun and have a combined mass more than 30 times greater than the Sun. The AB pair is one of the more massive binary systems in the Milky Way. It is in a stable orbit, but the C, D, and E stars are not, and gravitational forces may well throw them out of the system in the future.

Theta (θ) Orionis, perhaps better known as the Trapezium, appears to the naked eye to be a single star, but is revealed by any telescope to be a quadruple system. Theta Orionis provides much of the ultraviolet radiation that illuminates the Orion Nebula (see p.241). All four stars are hot O- and B-type stars, the largest being Theta-1 C, with 40 times the

mass of the Sun, about 200,000 times its luminosity, and a temperature of 72,000°F (40,000°C). Theta-1 C is the hottest star visible to the naked eye. Theta-1 A is an eclipsing double star with an additional companion; Theta-1 D is a double star; and Theta-1 B is an eclipsing binary star, with a companion double (making it quadruple in itself). Although known as a quadruple star, Theta Orionis in fact consists of at least ten stars. THE TRAPEZIUM GROUP

The stars of Theta Orionis light up the center of the Orion Nebula. A false-color image (below) helps to define the four main stars in the system.

DOUBLE STAR

Epsilon Aurigae DISTANCE FROM SUN

2,040 light-years MAGNITUDE

3

SPECTRAL TYPE

A8

AURIGA

The hot giant Epsilon (ε) Aurigae, or Almaaz, is an eclipsing binary star. Unusually, its eclipse lasts for two years, suggesting that the system is huge. The giant star is being eclipsed by something far bigger than itself, but exactly what is uncertain. One theory is that Epsilon Aurigae’s companion is an unseen star surrounded by a huge, dusty ring, and the bright star shines through this ring during an eclipse. DISTANT BINARY

Dwarfed in this image by its celestial neighbor Capella, Epsilon Aurigae is in fact some 2,000 light-years more distant.

TH E MI L KY WAY

ORION

SIGMA ORIONIS’S FOUR BRIGHT STARS

B7

CLOSE BINARY

QUADRUPLE STAR

Sigma Orionis

281

282

VARIABLE STARS

VARIABLE STARS ALTHOUGH AT FIRST SIGHT

44 Measuring expansion 232–33 Stars 238–39 Star formation 266–67 Stellar end points 274–75 Multiple stars Extra-solar planets 296–99

the stars in the night sky seem to be unchanging, many thousands of stars change their brightness over periods ranging from a few days to decades. True, or intrinsic, variable stars vary in brightness due to physical changes within the star. Others, such as eclipsing binaries (see p.274), only appear to vary because they have orbiting companions. coolest state

hottest state

star expands and contracts (exaggerated here)

LUMINOSITY

Period of one pulsation

TIME

PROTOTYPE

Mira is one of the most famous variable stars in the Milky Way (see p.285). It is a long-period, pulsating star that has given its name to one of the main types of variable stars.

PULSATING VARIABLES Pulsating variable stars are intrinsic variables that undergo repetitive expansion and contraction of their outer layers. A pulsating star is constantly trying to reach equilibrium between the inward gravitational force and the outward radiation and gas pressure. This causes the star’s brightness to vary. In many types of pulsating stars, including Cepheids (see p.286), a star’s period of LIGHT CURVE variation is related to its luminosity. Knowledge of the The light curve of a star’s luminosity, coupled with its apparent magnitude, Cepheid variable shows enables astronomers to calculate a star’s distance. Pulsating the regular variation in variables are therefore a useful tool for determining luminosity during a period of one pulsation. distances to far-away objects such as other galaxies.

NOVAE

T H E M I L K Y WAY

A nova is a binary system, consisting of a giant star that is being orbited by a smaller white dwarf. The giant star has grown so large that its outer material is no longer gravitationally bound to the star and instead falls onto the white-dwarf companion. Eventually, this gain in material triggers a thermonuclear explosion on the surface of the white dwarf, which brightens it by many magnitudes, increasing its energy output by a factor of a million or more. The surface gases of the white dwarf are in a “degenerate” state, and they do not obey the normal gas laws. Usually a gas explosion will cause the gas to expand, thereby reducing the explosion and finishing it. However, the degenerate gases of a white dwarf do not expand, and the explosion turns into a runaway event that does not finish until the fuel is exhausted. Prior to this, the binary system would be invisible to the naked eye, and the nova outburst would then bring the system into visibility as a “new”—in Latin, nova—star.

MAY 20, 2002

SEPTEMBER 2, 2002

CATACLYSMIC BINARY

The most widely studied nova, Nova Cygni 1992, was witnessed exploding in 1992 (see p.287). Its magnitude rose by such a degree that at its brightest the nova was visible to the naked eye. exploded star

hot bubble of gas

LIGHT ECHOES

In 2002, the star V838 Monocerotis (see p.265) emitted an outburst of light that echoed off the surrounding dust. The star has been imaged several times since. At first thought to be a nova, it might in fact be a new type of eruptive star.

OCTOBER 28, 2002

283

TYPE I SUPERNOVAE As in a nova (opposite), the source of a type I supernova is a binary system consisting of a giant star and a white dwarf. In type I supernovae, rather than triggering a nova, the material transfer onto the white dwarf continues to increase the mass of the star until it collapses and then explodes, destroying itself. The class of type I supernovae is subdivided depending on which chemical elements are present in the supernova’s spectrum. In type Ia supernovae, the core of the white dwarf reaches a critical density, triggering the fusion of carbon and oxygen. This fusion is unconstrained and results in a massive explosion, with an associated leap in luminosity and the large companion ejection of matter into interstellar space. According to theory, all type Ia star supernovae have identical luminosities. This means that the distance to a supernova of this type can be determined by comparing its intrinsic luminosity with its material being Supernova pulled from apparent brightness. 1994D companion star

POWERFUL SUPERNOVA

white dwarf

This white-dwarf star pulls gas from a larger companion. Its mass rises until it can no longer support itself and it collapses in a huge explosion.

DISTANT SUPERNOVA

Like other type Ia supernovae, 1994D, seen in the outskirts of the distant galaxy NGC 4526, has an intrinsic brightness that allows its distance to be known.

BIZARRE VARIABLES

MYSTERIOUS STAR

One of the strangest stars known to astronomers, Epsilon Aurigae is a giant star that is being eclipsed by something even bigger than itself. One theory is that it is being orbited by a large dusty disk surrounding a companion.

OCTOBER 23, 2004

SEPTEMBER 9, 2006

TH E M I LK Y WAY

DECEMBER 17, 2002

Many variable stars exhibit magnitude variations that are regular, and are easily explained by eclipsing or by a pulsation mechanism occurring in a star’s outer layers. However, there are other variable stars whose magnitude variations seem to defy explanation. One example is Epsilon (ε) Aurigae or Almaaz, a giant star with eclipses that last for two years, far longer than expected for a normal eclipsing system. As Almaaz is itself huge, whatever is eclipsing it must be even larger, but in the absence of decisive observations astronomers can only theorize. One theory is that there is an unseen companion star or stars surrounded by a large dust ring, and it is the extended dust ring that eclipses Almaaz. Another bizarre variable is R Coronae Borealis (R CrB). This star can suddenly drop eight magnitudes, a large range that cannot be explained by physical changes within the star’s structure (see p.287). The variation cannot be due to an eclipse, since the drop in magnitude is irregular and not periodic. Some astronomers have suggested that an orbiting dust cloud is responsible, but the more popular theory is that R CrB is ejecting material from its surface and this ejected material blocks the light from the star before being blown away. Although the majority of variable stars are well understood, even to the extent that they can be used as reliable distance indicators, there are many individual stars that require further study before they reveal their secrets.

284

VARIABLE STARS More than 30,000 variable stars are known within the Milky Way, and it is likely that there are many thousands more waiting to be discovered. Variable star research is a fundamental and vital branch of astronomy, as it provides information about stellar masses, temperatures, structure, and evolution. Variable stars often have periods ranging from years to decades, and professional astronomers do not have the resources to continuously IRREGULAR VARIABLE The brightness of the variable star, monitor such stars. Consequently, amateur astronomers Gamma (γ) Cassiopeiae, changes play a key role within this field, submitting thousands irregularly and unpredictably by of observations into an international database. up to two magnitudes. ROTATING VARIABLE

Procyon DISTANCE FROM SUN

11.4 light-years MAGNITUDE

0.34

SPECTRAL TYPE

F5

CANIS MINOR

to Earth. Procyon has a companion, Procyon B, a white-dwarf star about the same size as Earth. Procyon shows small changes in magnitude, caused by surface features, such as star spots, passing in and out of view, as the star rotates. This type of variation classifies Procyon as a BY Draconis-type variable. In addition to surface changes, the tiny, brighter, companion also increases the apparent brightness of Procyon when it passes in front of the star as seen from Earth.

Procyon is only about seven times as luminous as the Sun, but appears bright in the sky due to its proximity

CONSPICUOUS VARIABLE

Seven times more luminous than the Sun, Procyon is the eighth-brightest star in the night sky.

ERUPTIVE VARIABLE

ECLIPSING BINARY

U Geminorum

Lambda Tauri

DISTANCE FROM SUN

DISTANCE FROM SUN

250 light-years MAGNITUDE

370 light-years

8.8

SPECTRAL TYPE

MAGNITUDE

B

3.4

SPECTRAL TYPE

B3

GEMINI

TAURUS

The prototype cataclysmic variable star, U Geminorum, is a close binary system, consisting of a red mainsequence star orbiting and eclipsing a white dwarf and its accretion disk. Material falls from the main-sequence star onto the disk, causing localized heating and rapid increases in brightness of three to five magnitudes.

Lambda (λ) Tauri is an Algol-type eclipsing binary (see p.274). The primary eclipse occurs every 3.95 days, during which the brightness drops by half a magnitude— noticeable to the naked eye. The two stars involved are a bright spectraltype-B3 dwarf and a giant of spectral type A4. The eclipses are partial eclipses, since only a part of each star is hidden by the other as it orbits. The stars are very close to each other, separated by only about 9 million miles (15 million km). Such proximity leads to tidal distortions in the stars, and perhaps mass exchange, leading to magnitude variations even when they are not eclipsing.

PROTOTYPE

U Geminorum lends its name to a type of irregular variable star that displays sudden increases in brightness.

ECLIPSING BINARY

Eta Geminorum DISTANCE FROM SUN

349 light-years MAGNITUDE

3.3

SPECTRAL TYPE

M3

TH E M I LKY WAY

GEMINI

Commonly known as Propus, Eta (η) Geminorum is a red giant star, and its red coloring is very apparent through binoculars. It is a semi-regular variable star with a 0.6-magnitude variation— ranging between magnitudes 3.3 and 3.9—over 234 days. Propus is also a spectroscopic eclipsing binary, having a cool spectral-type-B companion star orbiting it with a period of 8.2 years and at a distance of about 625 million miles (1 billion km). Propus is therefore eclipsed every 8.2 years and is a target for amateur variable-star observers. A second star orbits at a greater distance, with a period of 700 years, but with no eclipsing. Although Propus is a cool star, with

a temperature of about 6,500°F (3,600°C), it is more than 2,000 times as luminous as the Sun. Its temperature and luminosity suggest that it is 130 times larger than the Sun. This agrees with optical measurements, but there is some uncertainty—the star has different sizes when observed at different wavelengths, due to dark bands of titanium oxide in its spectrum. This uncertainty in measuring Propus’s size is typical of large, cool stars. Propus is evolving—observations by amateur

astronomers show that its average brightness has increased by 0.1 magnitude over the last decade. It has a dead helium core and is slowly entering a new phase: it is destined to become a Mira variable (see opposite).

ETA GEMINORUM OCCULTED

In an event that takes less than one-thirtieth of a second (above), Propus is occulted by the moon (see p.71). In an optical image (top) Propus is pictured alongside the much more distant supernova remnant IC 443.

285 ECLIPSING BINARY

EXPLORING SPACE

PULSATING VARIABLE

Alpha Herculis

WONDERFUL MIRA

Mira

DISTANCE FROM SUN

DISTANCE FROM SUN

382 light-years

418 light-years

MAGNITUDE

3

SPECTRAL TYPE

MAGNITUDE

M5

3

SPECTRAL TYPE

M7

HERCULES

CETUS

Alpha (α) Herculis, or Ras Algethi, is a cool red supergiant star that varies in brightness by almost one magnitude over a period of about 128 days. It is a complex star system with a much smaller companion that is itself a binary, consisting of a giant and a Sun-like star. There is a strong wind of stellar material blowing from the star, which reaches and engulfs its companions. Alpha Herculis is wider than the orbit of Mars. The outer atmosphere of the supergiant is slowly being removed, and the star will eventually become a white dwarf.

Omicron (ο) Ceti, better known as Mira, is among the best known of all variable stars. At its brightest, it reaches second magnitude, and at its faintest it drops to tenth—far too faint for the naked eye. It undergoes this variation with a period of 330 days. Therefore an observer can find Mira when it is at its brightest and over a period of time watch it completely disappear. Although Mira is one of the coolest stars visible in the sky, with a temperature of just 3,600°F (2,000°C), it is at least 15,000 times more luminous than the Sun. Internal changes in the star have left it so distended that the Hubble Space Telescope has revealed that it is not perfectly spherical (right). The variation in Mira’s magnitude is caused by pulsations that cause temperature changes and therefore changes in the star’s luminosity. Furthermore, Mira is shedding material from its outer layers in the form of a stellar wind. In the future, Mira will lose its outer structure and be left as a small white dwarf. In this way, Mira represents the future of the Sun.

GREAT CONTRAST

Although they are not particularly bright, the great contrast in size and color of the stars that make up Alpha Herculis allow them to be separated easily through a telescope.

IRREGULAR VARIABLE

Gamma Cassiopeiae DISTANCE FROM SUN

613 light-years MAGNITUDE

2.4

SPECTRAL TYPE

B0

CASSIOPEIA

A hot blue star with a surface temperature of 45,000°F (25,000°C), Gamma (γ) Cassiopeiae is about 70,000 times more luminous than the Sun. It is a variable star with unpredictable changes in magnitude. Astronomers have observed it as bright

When Dutch astronomer David Fabricius discovered Mira in 1596, it was the first long-period variable star to be recognized. In 1642 Johannes Hevelius named the star Mira, meaning “wonderful.” It has become the most famous longperiod pulsating variable in the sky, and one of the most popular stars for amateur astronomers. The American Association of Variable Star Observers has received more than 50,000 observations of Mira by over 1,600 observers.

as 1st magnitude and as faint as 3rd magnitude. It may have been fainter in ancient times, which might explain its lack of a common name. Gamma Cassiopeiae is a Be star (see panel, right), rotating at more than 625,000 mph (1 million km/h) at its equator and shedding material from its surface. The ejected material forms a surrounding disk, and it is the disk that makes varying and unpredictable emissions. Gamma Cassiopeiae may also be transferring material to an undiscovered dense companion star. NAMELESS STAR

Pictured here with the red-colored emission nebula IC 63, Gamma Cassiopeiae is among the most prominent stars in the sky that carries no common name.

THE ORIGINAL MIRA

Easily recognized in the night sky, Mira lends its name to a type of long-period variable, of which thousands are known.

GLOWING TAIL

Mira is shedding gas as it moves through space, producing a tail 13 light-years long that shows up at ultraviolet wavelengths, as seen in this image from NASA’s Galaxy Evolution Explorer.

DISTORTED SHAPE

Enhancement of Hubble’s Mira images reveals the star’s asymmetrical atmosphere in visible (left) and ultraviolet light (right).

EXPLORING SPACE

THE FIRST “BE” STAR When in 1866 Father Angelo Secchi, director of the Vatican Observatory and scientific advisor to Pope Pius IX, studied the spectrum of Gamma Cassiopeiae, he discovered that the star emitted light at particular wavelengths associated with hydrogen emission (see p.35). He is therefore credited with the discovery of the first Be star—a star of spectral type B but with “e” for emission. Be stars are characterized by their high rotation CENTRAL STAR speeds, high surface Gamma Cassiopeiae, temperatures, the brightest star in this and strong stellar image, is the central star winds focused into in the distinctive “W” of Cassiopeia (see p.357). equatorial disks.

TH E MI L KY WAY

286

VARIABLE STARS PULSATING VARIABLE

PULSATING VARIABLE

W Virginis

RR Lyrae

Delta Cephei

DISTANCE FROM SUN

DISTANCE FROM SUN

10,000 light-years

744 light-years

MAGNITUDE

9.6

SPECTRAL TYPE

MAGNITUDE

F0

EXPLORING SPACE

PULSATING VARIABLE

DISTANCE FROM SUN

982 light-years

7.1

MAGNITUDE

F5

SPECTRAL TYPE

4

SPECTRAL TYPE

F5

VIRGO

LYRA

CEPHEUS

W Virginis lends its name to a class of variable stars that are similar to Cepheid variables (see p.282) and are also known as Population II Cepheids. W Virginis is a pulsating yellow giant star. The outer layers of its atmosphere expand and contract with a period of 17.27 days. The period has lengthened over the last 100 years of observation. The pulsation causes a 1.2-magnitude variation, as the star doubles its size during the cycle. As a Population II star (see p.227), W Virginis is among the oldest stars in the Milky Way.

RR Lyrae is the brightest member of the class of variables that takes its name. RR Lyrae stars are similar to Cepheid variables (see p.282), but are less luminous and tend to have shorter periods—ranging from about 5 hours to just over a day. RR Lyrae’s period is 0.567 days, and its magnitude varies between 7.06 and 8.12. By comparing the luminosity of RR Lyrae variables with their apparent magnitude, a good distance determination can be made. In this way, RR Lyrae variable stars are important tools for calculating astronomical distances.

Delta (δ) Cephei is the prototype of the Cepheid class of variable stars (see p.282), and to astronomers it is one of the most famous stars in the sky. Its magnitude variation, from 3.48 to 4.37, is visible to the naked eye, and its short period of 5 days, 8 hours, and 37.5 minutes makes it a popular target for amateur observers. Its position in the sky makes it easy to find, and it is close to two comparison stars with magnitudes at the ends of Delta Cephei’s range. Delta Cephei is a supergiant with a spectral type that varies between F5 and G2.

BRIGHT VARIABLE

DOUBLE STAR

RR Lyrae has an average luminosity 40 times that of the sun and a surface temperature of about 12,000°F (6,700°C). RR Lyrae stars are often found in globular clusters, and they are sometimes referred to as cluster variables.

Delta Cephei is a double star, easily separated through a telescope. This false-color image clearly reveals its two component stars.

THE CEPHEID PROTOTYPE In 1921, Henrietta Leavitt (1868– 1921), an astronomer based at the Harvard Observatory, discovered a strong link between the period and luminosity of a group of stars later known as Cepheid variables (see p.282), of which Delta Cephei was the prototype. This correlation provided astronomers with a new way of measuring distances in space. In 1923, Edwin Hubble used it to prove that the Andromeda Galaxy is situated outside the Milky Way. Since then, Cepheids have provided more useful information about the universe than any other star type. HENRIETTA LEAVITT

W VIRGINIS

W Virginis is located high above the galactic plane in the diffuse halo of old stars that surrounds the Milky Way (see pp.226–29). Like other W Virginis variables, it is an old Population II star, on average lower in mass and magnitude than a Cepheid variable.

PULSATING VARIABLE

PULSATING VARIABLE

Zeta Geminorum

Eta Aquilae

T Coronae Borealis

DISTANCE FROM SUN

DISTANCE FROM SUN

1,168 light-years

1,400 light-years

MAGNITUDE

4

SPECTRAL TYPE

TH E M I LKY WAY

NOVA

MAGNITUDE

G0

DISTANCE FROM SUN

2,025 light-years

3.9

SPECTRAL TYPE

MAGNITUDE

F6

11

SPECTRAL TYPE

M3

GEMINI

AQUILA

CORONA BOREALIS

Also known as Mekbuda, Zeta (ζ) Geminorum is a yellow supergiant, about 3,000 times as luminous as the Sun. It is one of the easiest Cepheid variable stars to observe (see p.282). Zeta Geminorum, like all Cepheids, is unstable and pulsates, changing its temperature, size, and spectral type. It has a period of 10.2 days and a magnitude that varies from 3.6 to 4.2. Its period is shortening at the rate of about three seconds per year. Zeta Geminorum is also a binary star, with a faint, magnitude-10.5 companion.

Eta (η) Aquilae is a yellow supergiant star, with a luminosity 3,000 times that of the Sun. It is one of the brightest Cepheid variables in the night sky (see p.282), and also one of the first to be discovered. Eta Aquilae varies in magnitude from 3.5 to 4.4 over a period of 7.2 days. Such a brightness variation is easily detectable with the naked eye. The magnitude range, by coincidence, is the same as the prototype of the class, Delta Cephei (above). Over this period, Eta Aquilae also varies in spectral type between G2 and F6.

T Coronae Borealis (T CrB), also known as the Blaze Star, is a recurrent nova (see p.282). It has displayed two major outbursts, one witnessed in 1866, the other in 1946. T CrB’s usual apparent magnitude is 10.8, but during outbursts it has reached 2nd or 3rd magnitude. T CrB is a spectroscopic binary, consisting of a red giant of spectral type M3, and a smaller blue-white dwarf. T CrB is usually about 50 times as luminous as the Sun, but during outbursts it becomes more than 200,000 times as luminous. In between the outbursts,

BLAZE STAR

Although T Coronae Borealis cannot usually be seen without a telescope, during eruptions it has “blazed” bright enough to be seen with the naked eye.

stellar dust and gas from the outer layers of the red giant are drawn onto the white dwarf. Eventually, the total mass of the white dwarf reaches a critical level, causing the outer layers of the white dwarf to explode violently. After the explosion, the two stars return to normal, to repeat the process many years later.

287 PULSATING VARIABLE

Mu Cephei DISTANCE FROM SUN

5,258 light-years MAGNITUDE

4

SPECTRAL TYPE

M2

CEPHEUS

Mu (μ) Cephei, or the Garnet Star, is also known as Herschel’s Garnet Star, after the pioneering Germanborn astronomer William Herschel, who first described its distinctive red color and noted its resemblance to the precious stone garnet. Mu Cephei is one of the most luminous stars in the Milky Way, outshining the Sun by a factor of more than 200,000. A red supergiant, it is also one of the largest stars that can be seen with the naked eye. Its great size means that if placed in the Sun’s position at the center of the solar system, its outer layers would fall between Jupiter and Saturn. As with most large supergiants, Mu Cephei is an unstable star, expanding and contracting in diameter with a corresponding variation in magnitude. It is classed as a semi-regular supergiant variable with a spectral type of M2 and a magnitude varying between 3.43 and 5.1. It has two periods of variation (730 and 4,400 days) overlaid on one another. The pulsations of Mu Cephei, caused by internal absorption and release of energy, have thrown off the outer

NOVA

layers of the star’s atmosphere, creating concentric shells of dust and gas around it. Observations have also shown that Mu Cephei is surrounded by a sphere of water vapor. Mu Cephei probably started its life as a star of around 20 solar masses. Typically for such a high-mass star, it has evolved very rapidly, and we are seeing it as it hurtles headlong toward

DISTANCE FROM SUN

DISTANCE FROM SUN

2,000–5,000 light-years

6,037 light-years

12.5

SPECTRAL TYPE

MAGNITUDE

M2

Known for its distinctive color, Mu Cephei, or the Garnet Star, is the bright reddishorange star at the top left of the image. It is pictured above the red emission nebula IC 1396 (see p.243).

Nova Cygni 1992

R Coronae Borealis MAGNITUDE

VARIABLE JEWEL

NOVA

IRREGULAR VARIABLE

RS Ophiuchi

the end of its short life. One day soon (on an astronomical timescale), Mu Cephei will erupt in a cataclysmic supernova, after which only the core will remain, ending its days as a neutron star or black hole.

DISTANCE FROM SUN

10,430 light-years

5.9

SPECTRAL TYPE

MAGNITUDE

G0

4.3

SPECTRAL TYPE

Q

CORONA BOREALIS

CYGNUS

RS Ophiuchi is a recurrent nova (see p.282), having been witnessed erupting in 1898, 1933, 1958, 1967, 1985 and, most recently, in 2006. During its periods of normality, it shines at magnitude 12.5, but during outbursts it has reached 4th magnitude. While RS Ophiuchi is usually invisible to the naked eye, during outbursts it can be seen in the night sky without a telescope. RS Ophiuchi is classed as a cataclysmic variable—a binary system consisting of a giant star shedding material and a dwarf companion receiving the material. Eventually a thermonuclear explosion is triggered on the surface of the dwarf, resulting in the ejection of a shell and an increase in brightness. RS Ophiuchi is constantly monitored by amateur astronomers, and the American Association of Variable Star Observers has more than 30,000 observations in its database.

The prototype of a class of variable stars, R Corona Borealis (R CrB) drops in magnitude from 5.9 to 14.4 at irregular intervals. There are two theories for this variation. One is that an orbiting dust cloud obscures R CrB when it passes in front of the star. The other is that R CrB ejects material, which obscures the light the star emits, before being blown away.

Nova Cygni 1992, a cataclysmic binary, was discovered on the night of February 18–19, 1992, shining with a magnitude of 7.2 at a location where there should have been no such star. The discoverer, Peter Collins (see p.80), alerted astronomical authorities, and soon a whole range of instruments, both ground-based and spaceborne (including the Voyager spacecraft), were observing it at a variety of wavelengths. Over the next few days, the nova continued to brighten to magnitude 4.3, making Nova Cygni 1992 not only the first nova to be observed so extensively, but also the first to be thoroughly observed before it had reached its peak. The nova eruption was the result of material falling from one star onto a white dwarf, triggering an explosion and the

FALSE-COLOR INFRARED IMAGE

BRIGHT NOVA

Nova Cygni 1992 was one of the brightest nova to be witnessed erupting in recent history. Targeted by some of the most powerful telescopes in the world, it could be seen, at its brightest, with the naked eye. HOT BUBBLE

This Hubble Space Telescope photograph reveals the irregularly shaped bubble of hot stellar material blasted into space by the eruption of Nova Cygni 1992.

ejection of a shell of material. The Hubble Space Telescope observed the system in 1993, detecting the ring thrown out by the binary system and also an unusual barlike structure across the middle of the ring, the origin of which is unknown.

TH E MI L KY WAY

OPHIUCHUS

288

STAR CLUSTERS

STAR CLUSTERS 24–25 Celestial objects 227 Stellar populations 229 The edges of the Milky Way 234–37 The life cycles of stars 238–39 Star formation 274–75 Multiple stars

ALTHOUGH THE STARS

in our night sky appear to live out their lives in isolation, many millions of stars reside in groups called open and globular clusters. Open clusters are young and often the site of new star creation, whereas globulars are ancient, dense cities of stars, some of which contain as many stars as a small galaxy.

OPEN STAR CLUSTERS

TH E MI L KY WAY

Open clusters are made up of “sibling” stars of similar age formed from the same nebulous clouds of interstellar gas and dust. This often results in stars within an open cluster having the same chemical composition. However, an open cluster’s stars can exhibit a wide range of masses, due to variations within the original nebula and other influences during their formation. Open clusters reside within the galactic plane, and often remain associated with the nebulous clouds from which they were produced. Open clusters do not hold on to their stars for long—as they orbit the center of the galaxy, they lose their members over a period of hundreds of millions of years. More than 2,000 open clusters have been discovered within the Milky Way, representing perhaps only 1 percent of the total population.

LARGEST CLUSTER

The largest globular cluster in the Milky Way, Omega (ω) Centauri probably contains more than 10 million stars. This makes it larger than some small galaxies.

YOUNG OPEN CLUSTER

Spanning an area in the sky larger than a full moon, M39 is a large but sparsely populated open cluster. It contains about 30 loosely bound stars, each around 300 million years old, and therefore much younger than the Sun.

STAR CLUSTERS

289

GLOBULAR CLUSTERS

DENSE CLUSTER

An image of part of the Omega (ω) Centauri globular cluster, captured in red light, reveals a great swarm of tightly bound stars. Omega Centauri is one of the densest and most populated globular clusters known within the Milky Way or beyond.

old red giant

A globular cluster is a massive group of stars bound together by gravity within a spherical volume. Globular clusters can contain between 10,000 and several million stars, all within an area often less than 200 light-years across. As in open clusters, the stars within a globular cluster all have the same origin, and thus similar ages and chemical compositions. Spectroscopic studies of the starlight from globulars reveal that their stars are very old— older than most of the stars currently within the disk of the Milky Way. Analysis of their properties also reveals that they are about the same age, implying that they all formed together, over a short period of time. Estimates of their ages vary, but they are thought to be over 10 billion years old. More than 150 globular clusters have been discovered in the Milky Way. Although a few are found in its central bulge, most are located in the halo. The chemistry of globular clusters shows that they represent the remnants of the early stages of the formation of the Milky Way, and perhaps formed even before the Milky Way had a disk. Four globulars may have originally been part of a dwarf galaxy that has been absorbed into the Milky Way. Globular clusters are made up of Population II stars (see p.227), which have their own independent orbits. These orbits are highly elliptical, and can take the globulars out to distances of hundreds of thousands of light-years from the center of the Milky Way. Globular clusters are not unique to the Milky Way, and some galaxies have more globular clusters than our own.

BLUE STRAGGLERS “blue straggler”

In the central region of the globular cluster NGC 6397, among its old red stars, are seen a few young blue stars. These stars, called “blue stragglers,” are thought to have been created by densely packed stars colliding.

CLUSTER EVOLUTION Star clusters, whether open or globular, are not static through time. Over millions of years, the clusters change physically and the stars within them age and die. However, there are major differences between the evolution of globular clusters and open clusters. An open cluster starts its life with a set of stars of similar chemical composition and age. Over hundreds of millions of years, it loses its members, either due to death of the stars or losing them to the gravitational tugs of other stars within the Milky Way. However, an open cluster can continue to manufacture stars from the original nebulous cloud from which it formed. Because of this, open clusters often contain stars of different ages at various stages of evolution. A globular cluster is more tightly bound, and less likely to lose its stars. It also spends most of its time away from the disk of the Galaxy, avoiding interactions. In this way its structure is preserved for thousands of millions of years—far longer than open clusters. Similarly, once a globular cluster has formed, the original gas and dust is ejected, and the cluster is then unable central bulge to form new stars. As the stars within a globular cluster age and die, so the cluster itself ages and dies.

CLUSTER DISTRIBUTION

The difference in the distributions of open and globular clusters within the Milky Way reflects their differences in age and orbit. Open clusters, formed from relatively young, Population I stars, are located within the Milky Way’s rotating disk. Globular clusters, made up of Population II stars, have independent orbits mostly located out in the Milky Way’s halo.

halo

globular clusters

spiral arm

At about 1 billion years old, NGC 2266 is a relatively old and well-evolved open cluster. Many of its stars, clearly seen here, have reached the red-giant stage of their life cycle, while young blue stars are also present.

open clusters

TH E M I LKY WAY

EVOLVED CLUSTER

290

STAR CLUSTERS More than 2,000 open clusters have been cataloged in the Milky Way. About half contain fewer than 100 stars, but the largest have more than 1,000. Open clusters are asymmetrical and range in size from 5 to 75 light-years across. By contrast, globular clusters contain up to a million stars, spread symmetrically across several hundred light-years. Only about 150 MASSIVE CLUSTER Omega Centauri is a prime example globular clusters are known in the Milky Way and, unlike of a globular star cluster. It contains open clusters, which are found mainly in the Galaxy’s more than 10 million old stars and has a mass of 5 million solar masses. spiral arms, most are scattered around the periphery. OPEN CLUSTER

Hyades CATALOG NUMBER

MEL 25 DISTANCE FROM SUN

150 light-years MAGNITUDE

0.5

TAURUS

The Hyades cluster is one of the closest open clusters to Earth and has been recognized since ancient times. The brightest of the cluster’s 200 stars form a V-shape in the sky, clearly visible to the naked eye. The cluster’s central group is about 10 light-years

in diameter, and its outlying members span up to 80 light-years. Most of the stars in this cluster are of spectral classes G and K (see pp.232–33) and are average in size, with temperatures comparable to that of the Sun. The brightest star in the field of the Hyades, the red giant Aldebaran (see p.256), is not a member of the cluster and is much closer to Earth. The cluster’s stars all move in a common direction, toward a point east of Betelgeuse in Orion (see p.256). Studies of the movement of the stars of the Hyades show that they have a common origin with the Beehive Cluster (see below). The Hyades cluster is thought to be about 790 million years old, and this age matches that of the Beehive Cluster. The parallel movement of stars in the Hyades has allowed their distance to be measured, using the moving cluster method for stellar distances (see pp.232–33). PROMINENT CLUSTER

First recorded by Homer around 750 BC, the Hyades is one of the few star clusters visible to the naked eye. Aldebaran, the bright red giant in this image, is not part of the cluster, but is 90 light-years closer to Earth.

OPEN CLUSTER

OPEN CLUSTER

Beehive Cluster

Butterfly Cluster CATALOG NUMBERS

M6, NGC 6405 DISTANCE FROM SUN

2,000 light-years MAGNITUDE

5.3

SCORPIUS

The Butterfly Cluster, located toward the center of the Milky Way, is about 12 light-years across and has an estimated age of 100 million years. In the night sky, the cluster occupies an area the size of a full moon, and, to some, it resembles the shape of a butterfly. The cluster is made up of about 80 stars, most of them very hot, blue main-sequence stars with spectral types B4 and B5 (see pp.232–33). The brightest star in the cluster, BM Scorpii, is an orange supergiant star that is also a semiregular variable (see pp.282–83). At its brightest, this star is visible to the naked eye; at its faintest, binoculars are needed. The Butterfly Cluster displays a striking contrast between the blue main-sequence stars and the orange supergiant.

M93 CATALOG NUMBERS

CATALOG NUMBERS

M93, NGC 2447

M52, NGC 7654

DISTANCE FROM SUN

DISTANCE FROM SUN

DISTANCE FROM SUN

577 light-years

3,600 light-years MAGNITUDE

3,000–7,000 light-years

6

MAGNITUDE

7.5

CANCER

PUPPIS

CASSIOPEIA

The Beehive Cluster, also known as Praesepe, is easily visible to the naked eye. The cluster contains over 350 stars, spread across 10 light-years, but most of them can be seen only with a large telescope. It is thought to be about 730 million years old. Age, distance, and motion measurements suggest that the Beehive Cluster most likely originated in the same star-forming nebula as the Hyades (above).

M93 is a bright open cluster and, at about 25 light-years across, is relatively small. It lies in the southern sky, close to the galactic equator. The cluster consists of about 80 stars, but only a few of the stars, blue giants of spectral type B9 (see pp.232–33), provide most of the cluster’s light. At about 100 million years old, M93 is young in astronomical terms.

An open cluster of about 200 stars, M52 lies against a rich Milky Way background. It was first cataloged in 1774 by Charles Messier (see p.73). The distance to the cluster is uncertain, with estimates ranging from 3,000 to 7,000 light-years. The uncertainty is due to high interstellar absorption that affects the light from the cluster during its journey to Earth. The uncertain distance also means that the cluster’s size is unknown, but mid-range estimates give a size of about 20 light-years across. The age of the cluster is calculated to be about 35 million years. The brightest stars in M52 have magnitudes of only 7.7 and

CELESTIAL BEEHIVE

SOUTHERN CLUSTER

The Butterfly Cluster is one of the largest and brightest open star clusters in the Milky Way. It can best be seen with binoculars in a dark sky and can be located within the constellation Scorpius.

M52

M44

3.7

SKY SPECTACLE

OPEN CLUSTER

CATALOG NUMBER

MAGNITUDE

TH E M I LKY WAY

OPEN CLUSTER

CLUSTER AND NEBULA

This image, stretching more than twice the diameter of a full moon, captures the open cluster M52 (top left) and the glowing Bubble Nebula (bottom right).

8.2, and with an overall magnitude of 7.5 the cluster is too faint to be seen with the naked eye. However, through binoculars the cluster can be viewed as a faint nebulous patch, while a small telescope reveals a rich, compressed cluster of stars.

STAR CLUSTERS OPEN CLUSTER

Pleiades CATALOG NUMBER

NGC 1435 DISTANCE FROM SUN

380 light-years MAGNITUDE

4.17

GHOSTLY NEBULA TAURUS

The Pleiades, also known as the Seven Sisters, is the best-known open cluster in the sky, and has been recognized since ancient times (see panel, right). The cluster is easily visible to the naked eye, but although most people CLUSTERS IN TAURUS

The two best-known clusters, the Pleiades (boxed) and the Hyades (opposite), both lie in Taurus. However, the Pleiades is more than 200 light-years more distant.

This haunting image shows an interstellar cloud caught in the process of destruction by strong radiation from the star Merope in the Pleiades. The cloud is called IC 349 or Barnard’s Merope Nebula.

can see seven stars in the Pleiades, the seventh can often be elusive. Nine stars can be seen on a very dark and clear night. The nine brightest stars are known as the father, Atlas, the mother, Pleione, and the sisters Alcyone, Maia, Asterope, Taygeta, Celaeno, Merope, and Electra. Small telescopes and binoculars reveal many more stars, and larger telescopes show that the cluster, in fact, contains hundreds of stars. The Pleiades is about 100 million years old and will remain a cluster for only

another 250 million years or so, by which time it will have broken up into separate isolated stars. The stars of the Pleiades are blue giants of spectral class B (see pp.232–33) and are hotter and more luminous than the Sun. Long-exposure photography reveals that the Pleiades stars are embedded in clouds of interstellar dust. The clouds are illuminated by radiation from the stars, and they glow as reflection nebulae (see p.228). Although most gas and dust surrounding star clusters represents the material that gave birth to the stars, here the clouds are merely moving through the cluster. The clouds are traveling relative to the Pleiades at 25,000 mph (40,000 km/h), and will eventually pass through the cluster and travel into deep space, where they will once again become dark and invisible.

291

EXPLORING SPACE

BRONZE AGE CLUSTER The Nebra Disk is perhaps the oldest semi-realistic depiction of the night sky. It was discovered in 1999, near the German town of Nebra, and other artifacts found nearby have allowed it to be dated to about 1600 bc. The disk depicts a crescent moon, a full moon, randomly placed stars, and a star cluster likely to be the Pleiades. Although its authenticity remains uncertain, the Nebra Disk may be proof that European Bronze Age cultures had a more sophisticated appreciation of the night sky than had previously been accepted.

GLOWING NEBULOSITY

The stars of the Pleiades are surrounded by clouds of dusty material that are reflecting the blue light of the stars. However, the stars were not produced from this material, which seems simply to be passing by.

ANCIENT PLEIADES

The cluster of seven gold dots (above and right of center) has been interpreted as the Pleiades cluster as it appeared 3,600 years ago.

T HE M I L KY WAY

M9 GLOBULAR CLUSTER

Globular clusters are swarms of very old stars that were born long before the Sun. Most are concentrated toward the center of the Milky Way, including this one, M9, some 25,000 light-years away. M9 is estimated to contain a quarter of a million stars. In this image from the Hubble Space Telescope, hot blue stars and cooler red giants can be identified by their colors.

294

STAR CLUSTERS GLOBULAR CLUSTER

OPEN CLUSTER

M4

Jewel Box CATALOG NUMBERS

CATALOG NUMBER

M4, NGC 6121

NGC 4755

DISTANCE FROM SUN

DISTANCE FROM SUN

7,000 light-years MAGNITUDE

8,150 light-years

7.1

MAGNITUDE

4.2

CRUX

SCORPIUS

M4 is one of the closest globular clusters to Earth and can be seen with the naked eye on a dark, clear night. The cluster has a diameter of about 70 light-years and contains more than 100,000 stars, but about half the cluster’s mass resides within eight light-years of its center. The Hubble Space Telescope has revealed a planet within M4, with about twice the mass of Jupiter, orbiting a white dwarf star. The planet is estimated to be 13 billion years old.

DENSE CENTER

GLOBULAR CLUSTER

47 Tucanae CATALOG NUMBER

NGC 104 DISTANCE FROM SUN

13,400 light-years MAGNITUDE

GLITTERING JEWELS

The Jewel Box, also known as the Kappa Crucis cluster, is an open cluster of about 100 stars and is about 20 light-years across. At less than 10 million years old, it is one of the youngest open clusters known. The three brightest stars are blue giants, while the fourth-brightest star is a red supergiant. The different colors are very apparent in photographs of the cluster, hence its popular name. Lying within the constellation Crux, the Jewel Box is visible only to observers in the Southern Hemisphere.

4.9

TUCANA

47 Tucanae is so named because it was originally cataloged as a star—the 47th in order of right ascension in the constellation Tucana. In reality, it is the second-largest and secondbrightest globular cluster in the sky, containing several million stars— enough to make a small galaxy. These stars are spread over an area about 120 light-years across, and the cluster’s central region is so crowded that there

SOUTHERN SPECTACLE

An optical image (top) captures 47 Tucanae and the Small Magellanic Cloud (see p.311), a satellite galaxy of the Milky Way. A closeup of 47 Tucanae (boxed) reveals one of the most spectacular globular clusters in the sky.

is a high rate of stellar collisions. As a globular cluster ages, the stars within it also age, but 47 Tucanae is home to a number of blue stragglers—stars that are too blue and too massive to still be there if they were original members of the cluster. Astronomers have determined that it is the stellar collisions within the cluster that cause the formation of these blue stragglers.

GLOBULAR CLUSTER

GLOBULAR CLUSTER

NGC 3201

Omega Centauri

CATALOG NUMBER

CATALOG NUMBER

NGC 5139

NGC 3201

DISTANCE FROM SUN

DISTANCE FROM SUN

15,000 light-years

17,000 light-years

TH E MI L KY WAY

MAGNITUDE

5.33

MAGNITUDE

8.2

CENTAURUS

VELA

Omega Centauri is the largest globular cluster in the Milky Way—up to ten times as massive as other globular clusters. Containing more than 10 million stars and having a width of 150 light-years, Omega Centauri is as massive as some small galaxies. To the naked eye, it appears as a fuzzy star, but a small telescope starts to resolve its individual stars. Studies of the cluster’s stellar population have revealed that Omega Centauri is one of the oldest objects in the Milky Way—almost as old as the universe itself—and that there have been several episodes of star formation within the cluster. This is unusual for a globular cluster, and one explanation for this is that Omega Centauri may once have been a dwarf galaxy that collided with our own. It would have had about 1,000 times its current mass, but the Milky Way would have ripped it apart, leaving Omega Centauri as the remnant core.

The globular cluster NGC 3201 contains many bright red giant stars, which give the cluster an overall reddish appearance. The cluster lies close to the galactic plane, and so its appearance is further reddened by interstellar absorption. With a visual magnitude of only 8.2, the cluster is too faint to be seen with the naked eye. NGC 3201 is less condensed than most globular clusters, and several observers have suggested that some of the stars appear in short, curved rays, like jets of water from a fountain.

GIGANTIC GLOBULAR

Easily the biggest of all known globular clusters in the Milky Way, Omega Centauri has a mass of more than 5 million solar masses. The stars in this globular cluster are generally older, redder, and less massive than the Sun.

RED-TINGED CLUSTER

295 GLOBULAR CLUSTER

GLOBULAR CLUSTER

M12

NGC 4833 CATALOG NUMBERS

CATALOG NUMBER

M12, NGC 6128

NGC 4833

DISTANCE FROM SUN

DISTANCE FROM SUN

16,000 –18,000 lightyears MAGNITUDE

17,000 light-years MAGNITUDE

7.8

7.7

OPHIUCHUS

MUSCA

Discovered by Charles Messier (see p.73) in 1764, M12 was one of the first globular clusters to be recognized. M12 is at the very limit of naked-eye visibility and therefore best viewed with a telescope. The cluster contains many bright stars and is condensed toward the center. Its stars are spread across a distance of about 70 light-years, making it less compact than most. Because of this, M12 was originally regarded as an intermediate form of cluster, between open clusters and globular clusters, before the two types were recognized as being fundamentally different.

NGC 4833 is a small globular cluster in the southern constellation Musca and therefore is not visible to most observers in the Northern Hemisphere. It was discovered by Nicolas Louis de Lacaille (see p.422) during his 1751–52 journey to South Africa. Although NGC 4833 is too faint to see it with the naked eye, it is easily visible through a small telescope. However, because the cluster is rich and compact, even a moderate amateur telescope fails to resolve its stars fully. The center of the cluster is only slightly more dense than its surroundings, and consequently the cluster lacks the gravitational pull needed to hold on to its stars, and many have already left the cluster. NGC 4833 is located below the galactic plane behind a dusty region. The dust absorbs light from the cluster and causes its

starlight to redden. Because of this reddening, astronomers studying this globular cluster have had to correct the apparent magnitudes of the various stars being studied. The technique used is applied to all globulars lying near the galactic plane. The cluster contains at least 13 confirmed RR Lyrae variable stars (see pp.282–83), which have helped astronomers to estimate the cluster’s age at about 13 billion years. DISTANT GLOBULAR

EARLY DISCOVERY

GLOBULAR CLUSTER

GLOBULAR CLUSTER

M107

COMPACT CLUSTER

NGC 4833 was first recorded by Nicolas Louis de Lacaille in 1752 as resembling a comet. However, with modern, high-powered telescopes it is seen as a well-resolved and compact cluster, with a scattering of outlying stars.

pp.266–67) from the time when the cluster was young. Unusually, two of these pulsating neutron stars form a contact binary pair (see p.274). CATALOG NUMBERS

M107, NGC 6171

M68, NGC 4590

M15, NGC 7078

DISTANCE FROM SUN

DISTANCE FROM SUN

DISTANCE FROM SUN

27,000 light-years

33,000–44,000 lightyears

35,000–45,000 lightyears

9.7

MAGNITUDE

6.4

HYDRA

PEGASUS

A relatively “open” globular cluster lying close to the galactic plane, M107 is too faint to be seen with the unaided eye. Observations through large telescopes have revealed that the cluster contains dark regions of interstellar dust that obscure some of its stars. This is quite unusual in globular clusters. M107 spans a distance of about 50 light-years.

M68 is a globular cluster that is visible only through telescopes. It appears as a small patch when viewed with binoculars, but small telescopes can reveal its constituent stars and its densely populated center. The cluster has a diameter of about 105 lightyears, and its orbit around the center of the Milky Way means that it is approaching the solar system at about 250,000 mph (400,000 km/h). Although many variable stars (see pp.282–83) have been detected within the cluster—more than 40 to date, including RR Lyrae stars— the distance to M68 is still uncertain.

At the limit of naked-eye visibility, M15 is one of the densest globular clusters in the Milky Way. The cluster has a diameter of about 175 light-years, but, as the center of the cluster has collapsed in on itself, half of its mass is located within its one-lightyear-wide superdense core. M15 also contains nine pulsars, remnants of ancient supernova explosions (see

DENSE BALL

PACKED CORE

At its core, this globular cluster has the highest concentration of stars in the Milky Way outside the galactic center.

TRUE COLORS

The brightest stars in M15 are red giants, with surface temperatures lower than the Sun’s. Most of the fainter stars are hotter, giving them a bluish-white tint.

TH E M I LK Y WAY

OPHIUCHUS

LOOSE CLUSTER

8.3

The globular cluster known as M14 has a diameter of about 100 light-years and contains several hundred thousand stars. Because of its considerable distance, it is too faint to be seen with the naked eye, and, although binoculars or a small telescope will reveal the cluster, a larger instrument is needed to resolve individual stars. Many amateur observers mistakenly identify this object as an elliptical galaxy. In 1938, M14 was home to the first nova photographed in a globular cluster. However, subsequent searches with some of the world’s most powerful telescopes have failed to find either the nova star or any of its remnants.

M15

MAGNITUDE

DISTANCE FROM SUN

OPHIUCHUS

CATALOG NUMBERS

8.9

CATALOG NUMBERS

M14, NGC 6402

MAGNITUDE

CATALOG NUMBERS

MAGNITUDE

M14 23,000–30,000 lightyears

GLOBULAR CLUSTER

M68

GLOBULAR CLUSTER

296

EXTRA-SOLAR PLANETS

EXTRA-SOLAR PLANETS 25 Stars and brown dwarfs 90–91 Astronomical observatories 94–95 Observing from space 235 Formation of a planetary system 238–39 Star formation 274–75 Multiple stars

THE SUN IS NOT

the only star with a planetary system. More than 750 planets have so far been found orbiting other stars, with the list growing rapidly year by year. Extra-solar planets have been detected around stars of a range FLYING SAUCER DISK of types and ages, suggesting that planet A young star near Rho (ρ) Ophiuchi shines out from formation is a robust process and that within a dust disk that might contain planets. planetary systems are commonplace.

PLANET-FORMING DISKS Some of the first evidence leading to the detection of extra-solar planets, or exoplanets, was the discovery of flattened disks of material around some young stars. This fitted the standard theory of planetary-system formation (originally put forward to explain the origins of the solar system), in which planets form from a disk of dust and gas rotating around a star. Some such circumstellar disks—also called debris disks—are symmetrical, suggesting that they are in their early stages, before planet formation. Others are distorted or have gaps or other structural features that suggest that planets have formed and are disturbing material in the disks. For example, the young, Sun-like star HD 107146 is surrounded by a debris disk. A study of dust distribution within the disk has suggested the possible presence of a planet orbiting at a distance of about 4.3 billion to 6.2 billion miles (7 billion to 10 billion km) from the central star. Dusty disks are also found around mature stars. Vega (see p.253) is surrounded by an extensive dust disk, which is fully revealed only at infrared wavelengths. This fine dust is thought to be the debris from a large and relatively recent collision between Pluto-sized bodies orbiting the star at a distance of 8 billion miles (13 billion km). Irregularities in Vega’s debris disk also suggests the presence of at least one planet. DEBRIS DISK

T H E M I L K Y WAY

A debris disk surrounds the red dwarf AU Microscopii. Structural features within the disk suggest that planets are orbiting the star, though none has been found yet.

DENSE DISK

DUST DISK AND GIANT PLANET

In this composite image, the dark central area is the star Beta (β) Pictoris—direct radiation from the star has been removed. The yellow and orange regions are parts of a dust disk, while the white spot located near the star is a giant planet.

The disk around the Sun-like yellow dwarf HD 107146 lies face-on to Earth. The Sun is believed to have a similar debris disk beyond Neptune, called the Kuiper Belt (see p.208), but that of HD 107146 is 10 times thicker and contains 1,000 to 10,000 times more material.

EXTRA-SOLAR PLANETS

DETECTING EXTRA-SOLAR PLANETS As extra-solar planets are invariably much smaller and dimmer than their parent stars, detecting them presents many challenges. As of 2012, only about 30 or so have been found by direct imaging, which involves first blocking out the light from the parent star. All other exoplanet discoveries have been made by indirect methods. The most productive so far has been the Doppler spectroscopy or radial velocity method, which is based on the use of a sensitive instrument called a spectrograph. It relies on the fact that as an exoplanet orbits its parent star, its gravitational pull produces a tiny “wobble” in the star’s movement relative to Earth. A second indirect approach, proving increasingly productive, is the transit method, which involves looking for repeated slight dips in the brightness of a star as a planet passes in front of it. One advantage of this method is that it reveals the planet’s diameter. Several other indirect detection methods have also been employed, with varying success. These include gravitational microlensing (detecting variations in the lensing star exoplanet effect of a star’s gravitational field, caused by a planet orbiting the star) and the pulsar timing method, which detects exoplanets orbiting pulsars from slight anomalies in the timing of the pulsars’ radio pulses. planet tracks across BRIGHTNESS

face of star

THE TRANSIT METHOD

dip in star’s light curve

This approach involves observing repeated transits of a planet in front of its parent star. Each transit causes a slight dip in the star’s brightness—of the order of 0.01 percent for an Earth-size planet.

DOPPLER SPECTROSCOPY

An exoplanet’s orbit causes a “wobble” in the motion of its parent star. As a result, light waves coming from the star appear to be alternately slightly lengthened (red-shifted) and shortened (blue-shifted)—a phenomenon that can be detected by sensitive spectrographs (see p.33).

Earth

star

light blue-shifted as star moves toward Earth

path of light without gravitational lensing

GRAVITATIONAL MICROLENSING Earth

lensing star

exoplanet’s gravity modifies lensing effect

The gravitational field of a star acts like a lens that can bend light rays coming from a distant background star, thus magnifying that star as seen from Earth. The presence of an exoplanet orbiting the lensing star produces detectable variations in the degree of magnification, or lensing effect, over time.

exoplanet

DIRECT IMAGING

This composite image was made in 2004 with a telescope located at the Paranal Observatory in Chile. It shows a brown dwarf star (here appearing bright white) known as 2M1207 and a smaller red companion, thought to be a hot gas-giant planet. This red object is the first extra-solar planet ever to have been directly imaged.

This survey was initiated at the Lick Observatory in California, USA, but is now based on use of a spectrograph called HIRES at the Keck Observatory in Hawaii, USA. It has contributed several hundred exoplanet discoveries. The HST has been involved in the discovery of a handful of exoplanets. One of the first direct observations of an exoplanet, orbiting the star Fomalhaut, was achieved with the HST.

1990 HUBBLE SPACE TELESCOPE (HST)

1998 ANGLO-AUSTRALIAN PLANET SEARCH

2002 MAGELLAN This program utilizes a spectrograph mounted on twin telescopes at the Las Campanas Observatory in Chile. By 2010 it had discovered 9 exoplanets.

Canada’s first space telescope, MOST has been used to monitor giant exoplanets that transit their parent stars, and to study atmospheric changes on the planets during the transits.

2003 MOST

lensing effect caused by gravity of star

distant star

1987 LICK–CARNEGIE EXOPLANET SURVEY

This survey, based at the Anglo-Australian telescope in Sydney, Australia, searches for giant planets orbiting more than 240 nearby Sun-like stars. By 2012, it had discovered 29 exoplanets.

exoplanet’s orbit

light bent toward Earth

The organized search for exoplanets has a history going back to 1987. For each of the ongoing search programs, missions, or instruments listed below, the year in which it began operation is given.

A spectrograph installed at an observatory in southeastern France, ELODIE discovered over 20 exoplanets—including (in 1995) the first to be found orbiting a Sun-like star. ELODIE was replaced by an improved instrument, SOPHIE, in 2006.

exoplanet

light red-shifted as star moves away from Earth

SEARCHING FOR EXTRA-SOLAR PLANETS

1993 ELODIE/SOPHIE

TIME

wobble in star’s motion

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EXPLORING SPACE

THE KEPLER MISSION

been used to study the light coming from exoplanets that transit their parent stars. In 2005, Spitzer made some of the first direct captures of infrared light from an exoplanet (although it did not resolve that light into actual images).

2003 HARPS A super-sensitive spectrograph at the European Southern Observatory in La Silla, Chile, HARPS has detected some 150 planets circling Sun-like stars.

2006 COROT This French-led mission is dedicated to the detection of exoplanets by the transit method. By the end of 2011, it had detected more than 20 new exoplanets. 2009 KEPLER A NASA mission aimed at finding Earth-sized exoplanets (see left).

T H E M I L K Y WAY

The Kepler mission is designed to look for sun shade and characterize exoplanets in our galactic photometer neighborhood, using the transit method of housing detection. The mission’s space-based focus is the Kepler spacecraft, whose sole instrument is a photometer (light meter) housed within a telescope. It continually monitors 145,000 solar main-sequence stars. A particular emphasis is array to find Earth-like planets lying in or near the habitable zones around their respective stars (see p.299). In addition, the mission aims to determine how many of the billions of stars in our galaxy have such planets; to estimate how many planets there are in multiple-star systems; and to star determine the properties of stars trackers that harbor planetary systems.

2003 SPITZER SPACE TELESCOPE Spitzer has

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EXTRA-SOLAR PLANETS

PLANETARY SYSTEMS Multiple exoplanets have been observed orbiting a number of relatively close stars. The first system of this type to be identified, in 1999, was found orbiting Upsilon (υ) Andromedae A, a Sun-like star located approximately 44 light-years away. The system is now known to include at least four planets, all thought to be comparable in size to Jupiter. HR 8799, a young main-sequence star located 129 light-years from Earth, also has at least four high-mass planets orbiting it. This quartet of giants, which have been directly imaged, orbit inside a large debris disk that surrounds the star—at orbital radii that are two to three times those of the four gas giants orbiting our own Sun. This is surpassed by the star 55 Cancri A, which is part of a binary star system and one of just a handful of stars known to have at least five exoplanets—ranging from Neptune- to Jupiter-sized—in orbit around it. Systems have also been discovered in which one or more planets orbit both stars in a binary star system. Kepler-16b, for example, is an exoplanet comparable to Saturn in mass and size that follows a nearly circular 229-day orbit around two stars located some 196 light-years away.

Kepler-16b

PLANET ORBITING A BINARY STAR

The exoplanet Kepler-16b, discovered in 2011, orbits the binary star system Kepler-16. Here, the orbits of the two components of Kepler-16 (labeled stars A and B) are shown, together with the orbit of Kepler-16b and, for comparison, the size of Earth’s and Mercury’s orbits around the Sun. Kepler-16b is thought to be made up of about half rock and half gas.

B A

orbit of star B

orbit of star A

size of Earth’s orbit size of Mercury’s orbit

Upsilon Andromedae c

inclined, highly elliptical orbit

INCLINED ORBITS

Upsilon ( υ) Andromedae A

Upsilon (υ) Andromedae A is the primary member of a binary star system. Three of its four known planets, called Upsilon Andromedae b, c, and d, are shown here (the fourth planet orbits beyond planet d). The planets’ orbits are inclined to each other, and planets c and d have orbits that are highly elliptical. Planet d resides in the system’s habitable zone (see opposite). The innermost planet, Upsilon Andromedae b, orbits Upsilon (υ) Andromedae A every four days at a distance of 4.7 million miles (7.5 million km)—much closer than Mercury orbits the Sun.

Upsilon Andromedae b

GAS GIANTS

BROWN DWARF TWA 5B

The majority of exoplanets discovered so far have been giant planets, with sizes and masses ranging approximately between those of Neptune and Jupiter, and with small orbits. This is thought simply to reflect the fact that planets of this type are the easiest to detect. The first extra-solar planets to be found orbiting Sun-like stars were found to be massive gas giants. Many were found to have very short orbital periods and were circling close-in on their host stars—they appeared to be hellish places, slowly evaporating in the heat with typical surface temperatures of 2,000°F (1,100°C). The existence of these “roasters” or “hot Jupiters” came as a surprise, since theories of planet formation had indicated that giant planets should only form at large distances from stars.

The smaller of the two objects in this image is a brown dwarf, TWA 5B. This orbits a young triple star system known as TWA 5A (the larger object). Brown dwarfs are failed stars that can be confused with large planets. TWA 5B was the first to be found orbiting a pre-main-sequence star.

ESCAPING ATMOSPHERE

TH E M I LKY WAY

Upsilon Andromedae d

The “hot Jupiter”-type exoplanet HD 209458b orbits close-in on its parent star (seen here in an artist’s impression). In 2003–2004 astronomers discovered an extended ellipsoidal envelope containing hydrogen and other gases evaporating from the planet. It is thought this type of atmosphere loss may be common to all “hot Jupiters.”

EXOPLANET TEMPERATURES MAP

This map produced by the Spitzer Space Telescope shows temperature variation across the surface of the “hot Jupiter”type exoplanet HD 189733b. One side of the planet always faces its parent star. The hottest area is slightly displaced from the point on the planet exactly facing the star—evidence that fierce winds operate in its atmosphere.

EXTRA-SOLAR PLANETS

SMALLER EXOPLANETS

GEOFFREY MARCY The American astrophysicist Geoffrey Marcy (b.1954) is a leading figure in the detection and characterization of exoplanets. Since the 1980s, he and his closest collaborators have discovered over 250 exoplanets, including the first system of multiple planets around a Sun-like star (Upsilon (υ) Andromedae), the first Neptunesized exoplanet (Gliese 436b), and the first Saturn-sized exoplanets. He is a coinvestigator of the Kepler mission (see p.297).

KEPLER–20e

299

Since about 2005, particularly since the launch of the Kepler mission in 2009, the deployment of detection systems of increased sensitivity has meant that more exoplanet discoveries have been of objects that are either comparable to the size of Earth, or of “super-Earth” size (more massive than Earth but much smaller than the Solar System’s gas giants). It is now thought that such low- and medium-mass planets are actually more common than gas giants. Of the 2,300 candidate exoplanets discovered by Kepler up to December 2011, about 200 are Earth-sized ones. One that is now a confirmed planet, Kepler-20e, is notable as the first smaller-than-Earth exoplanet found orbiting a Sun-like star. However, along with a slightly larger planet in the same system, Kepler-20f, Kepler-20e is otherwise not very Earthlike as it orbits close to its host star and is far too hot to have liquid water on its surface. Rather more intriguing is another Kepler mission discovery, Kepler-22b, a super-Earth that lies within the habitable zone of its parent star (see below) and might just be an oceancovered rocky world like Earth.

VENUS

EARTH

EARTH-SIZED AND LARGER

Shown here are artists’ impressions of the first two Earth-sized extra-solar planets to be discovered, Kepler-20e and Kepler-20f, with Earth and Venus for size comparison. Also shown to scale is an impression of Kepler-22b, the first transiting extra-solar planet identified as being in orbit within the habitable zone of a Sun-like star.

KEPLER–20f

KEPLER–22b

LOOKING FOR EARTHS

By December 2011, the Kepler spacecraft had discovered over 2,300 candidate exoplanets. Here, the first 1,235 that it identified are shown silhouetted against their parent stars, which have been ordered by size from top left to bottom right and tinted to indicate star color. For reference, the Sun with Jupiter silhouetted against it is shown at the same scale. Around 50 of these candidate planets were found in the habitable zones of their surveyed stars.

distance to habitable zone increases with mass of star

Earth is only planet within solar system’s habitable zone

1

habitable zone habitable zone around low-mass stars is close to star 0.1 0.01

0.1

1

DISTANCE FROM STAR (1 = EARTH’S DISTANCE FROM THE SUN)

10

T HE M I L KY WAY

THE CANDIDATES

STAR’S MASS (1= THE SUN’S MASS)

Jupiter transiting Sun

If there is life elsewhere in the universe, it seems reasonable to expect to find it on a world similar to Earth: a rocky planet orbiting a mainsequence star. Evidence from the Kepler mission and other search programmes suggests that about 20 percent of Sun-like stars have at least one giant planet. Current techniques can be used to estimate the orbital parameters of gas giants around these stars and thereby identify those with stable, circular orbits that are not close-in on their respective stars. Within a significant proportion of such systems, there is likely to be an inner zone where rocky terrestrial planets may have formed, some of them within the habitable zones associated with those stars. Although to date no exoplanet closely resembling Earth has been found, the signs are encouraging that one or more may be found in the reasonably near future. Once detected, analysis of light reflecting from the planets’ atmospheres HABITABLE ZONE For life to develop on a planet, the for telltale signs of life, such as oxygen planet must lie within the host star’s and methane, should be possible—a “habitable zone,” where liquid water capacity for this is already present in can permanently exist on the surface. some existing telescopes involved in This zone’s extent depends on the the exoplanet search. star’s mass and luminosity.

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“The history of astronomy is a history of receding horizons.” Edwin Hubble

OUTSIDE THE BOUNDS of the Milky Way stretch vast gulfs of space, the realm of the galaxies. The closest are on our own galactic doorstep—there is even a small galaxy currently in collision with the Milky Way. The farthest lie billions of light-years away, at the edge of the visible universe—their light has been traveling toward Earth for most of time. Galaxies range from great wheeling disks of matter to giant, diffuse globes of billions of stars and from starless clouds of gas to brilliant furnaces lit up by star formation. They are also violent—despite their stately motion over millions and billions of years, collisions are frequent and spectacular. Collisions disrupt galaxies, sending material spiraling into the supermassive black holes at their centers, fueling activity that may outshine ordinary galaxies many times over. Galaxies influence their surroundings and form constantly evolving clusters and superclusters. At the largest scale, it is these galaxy superclusters that define the structure of the universe itself. COSMIC RING

A circlet of brilliant star-forming regions, 300 million light-years from Earth, surrounds the yellow hub of what was once a normal spiral galaxy. This ring galaxy, AM 0644-741, is probably the result of a cosmic collision with a smaller galaxy.

BEYOND THE MILKY WAY

302

TYPES OF GALAXY

TYPES OF GALAXY

EDGE-ON SPIRALS

NGC 4013 is a spiral galaxy that happens to lie edge-on to Earth. Such edge-on views reveal the thinness and flatness of spiral galaxies. This Hubble image displays the dense dust within the disk, and shows how few stars lie above or below the disk.

THROUGHOUT THE UNIVERSE, galaxies

exist in enormous diversity. These vast wheels, 34–37 Radiation globes, and clouds of material vary hugely in 38–39 Gravity, motion, and orbits size and mass—the smallest contain just a few Galaxy evolution 306–309 million stars, the largest around a million million. Some are just Galaxy clusters 326–27 a few thousand light-years across, others can be a hundred times that size. Some contain only old red and yellow stars, while others are blazing star factories, full of young blue and white stars, gas, and dust. The features of galaxies are clues to their history and evolution, but astronomers have only recently begun to put the entire story together—and there are still many gaps in their knowledge. 24–27 Celestial objects

THE VARIETY OF GALAXIES Galaxies can be classified by their shape, size, and color. At the most basic level, they are divided by NUMBERING ELLIPTICALS The class of an elliptical shape into spiral, elliptical, and irregular galaxies. Edwin Hubble (see p.45) devised a more precise classification, still used today, that subdivides these galaxy shapes. Hubble classed spiral galaxies as types galaxy is found by dividing the difference between its Sa to Sd—an Sa galaxy has tightly wound spiral arms, an Sd very loose arms. Spirals with a bar across long and short axes by the their center are classed as SBa to SBd. Hubble classed elliptical galaxies as E0 to E7 according to their long-axis length and then shape in the sky—circular galaxies are E0, and elongated ellipses E7. Elliptical galaxies appear as two- multiplying by ten, making dimensional ellipses, but in reality they are three-dimensional ellipsoids ranging from roughly ball-shaped this galaxy, M110, an E6. star clouds to cigar shapes. So Hubble’s classification does not reflect their true geometry, since an E0 long axis = 8.7 arc-minutes galaxy could be a cigar shape viewed end-on from Earth. Hubble also recognized an intermediate type of IRREGULAR GALAXY short axis = Clouds of stars that lack clear 3.4 arc-minutes galaxy—the lenticular (type S0), with a spiral-like disk, disk- or ellipse-like structure a hub of old yellow stars, but no spiral arms. Finally, Sb SPIRAL galaxy NGC 4622 are called irregular galaxies. irregular galaxies (type Irr) are usually small, rich in gas, The Small Magellanic Cloud dust, and young stars, but have few signs of structure. is one such irregular galaxy. ELLIPTICAL GALAXY

E0 ELLIPTICAL galaxy M89

E6 ELLIPTICAL galaxy M110

Balls of stars, from perfect spheres, through egg shapes (such as M59, pictured here) to cigar-shaped ellipsoids, are called elliptical galaxies. SPIRAL GALAXY

Vast, rotating disks of stars, dust, and gas are classed as spiral galaxies. Spirals have a ball-shaped nucleus inside a disk with spiral arms. M33 is a nearby spiral galaxy.

Sa SPIRAL galaxy NGC 7217

E2 ELLIPTICAL galaxy M32

S0 LENTICULAR galaxy NGC 2755

HUBBLE’S CLASSIFICATION

Hubble arranged his galaxy types in a fork shape, with ellipticals along the handle, and spirals and barred spirals as prongs. This excludes irregular galaxies. He thought his scheme indicated the evolution of galaxies—today astronomers know it is not so simple.

SPIRAL GALAXIES

B E Y O N D T H E M I L K Y WAY

Sc SPIRAL the whirlpool galaxy (M51)

Some 25–30 percent of galaxies in the nearby universe are spirals. In each one, a flattened disk of gas- and dust-rich material orbits a spherical nucleus, or hub, of old red and yellow stars, which is often distorted into a bar. Stars occur throughout the disk, but the brightest clusters of young blue and white stars are found only in the spiral arms. The space between the arms often looks empty viewed from Earth, but it is also full of stars. Above and below the disk is a spherical “halo” region, where globular clusters (see p.289) and stray stars orbit. Spiral galaxies rotate slowly— typically once every few hundred million years—but they do not behave like a solid object. Stars orbiting ORBITS IN SPIRALS farther away take longer Stars in the disk of a to complete an orbit spiral galaxy follow elliptical, nearly than those close to the circular orbits in a core. The resulting plane. Those in “differential rotation” is single the hub have wildly the key to understanding irregular orbits at a the spiral arms. multitude of angles. elliptical orbit

BARRED SPIRAL

Similar to our own galaxy, M83 (right) is a typical barred spiral, having a straight bar on either side of the galactic nucleus.

chaotic orbit

SBa BARRED SPIRAL galaxy NGC 660

SBb BARRED SPIRAL galaxy NGC 7479

SBc BARRED SPIRAL galaxy NGC 1300

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FLOCCULENT SPIRAL

The spiral galaxy NGC 4414 is flocculent, with bright stars clumped throughout the disk. Its star formation seems to be caused by local collapses of material rather than a large-scale density wave.

SPIRAL ARMS The continued presence of spiral arms in most disk-shaped galaxies was once a mystery. If the arms orbit more quickly near the nucleus, then, during a galaxy’s multi-billion-year lifetime, they would become tightly wrapped around the core. It now seems that the arms are in fact rotating regions of star formation, not rotating chains of stars themselves. The arms arise from a “density wave”— a zone that rotates far more slowly than the galaxy itself. The density wave is like a traffic jam—stars and other material slow down open clusters as they move into it and accelerate as they move out, but the of longerjam itself advances only slowly. The increased density helps lived stars move out to trigger the collapse of gas clouds and the start of star from formation. The strength of the density wave varies between spiral arm spirals. If the wave is strong, the result is a neat, “grand design” spiral with two clearly defined arms. If it is weak or nonexistent, disk stars will tend to form in localized regions, creating the more clumpy “flocculent” spirals.

In this diagram of an ideal galaxy, objects follow neatly aligned elliptical orbits around the nucleus. They travel fastest when close to the nucleus and slowest when farthest away. SPIRAL REALITY

In a real galaxy, the orbits do not line up neatly. The variety of alignments, coupled with the slower movement when farther from the nucleus, creates spiral zones in which objects are moving more slowly and so become bunched together.

young “OB” star clusters never move far from spiral arm before dying

new stars ignite in HII region (star-forming nebula)

DETAIL OF A SPIRAL ARM molecular cloud is compressed

density wave causes material to build up sparse stars orbit faster than the spiral arm and move into arm from behind

As material orbiting in a galaxy’s disk approaches the denser region marked by the spiral arm, it packs together. Dark molecular clouds form, some of which turn into star-forming nebulae (see pp.238–39). New stars of all kinds ignite here, but the brightest ones soon die, so they always mark the spiral arms.

B E Y O N D T H E M I L K Y WAY

PERFECT GALAXY

304

TYPES OF GALAXY

ELLIPTICAL GALAXIES Elliptical galaxies show little structure other than a simple ball shape. They span the range from the largest to the smallest galaxies. At one end, dwarf ellipticals are relatively tiny clusters of a few million stars, often very loosely distributed, appearing faint and diffuse. Such galaxies are scattered in the space between larger galaxies and must contain significant amounts of invisible material simply to hold them together. Some of this could be in a central black hole, but much of it seems to be mysterious “dark matter” (see p.27) scattered through the whole of ORBITS IN ELLIPTICAL GALAXIES the galaxy. At the other extreme lie the giant ellipticals—galaxies only The orbits of stars in an elliptical found near the centers of large galaxy clusters and often containing galaxy vary wildly, from circles to very many hundreds of billions of stars. Some giant ellipticals, called cD long ellipses, and are not confined to galaxies, have large outer envelopes of stars and even multiple any specific direction. concentrations of stars at their centers, suggesting they may have formed from the merging of smaller ellipticals. Almost all the stars in elliptical galaxies are yellow and red, and there is rarely any sign of star-forming gas and dust. The dominance of old, long-lived stars implies that any star formation in these galaxies has long since ended. Each star orbits the galaxy’s dense core in its own path. The chances of collision are very remote, because stars are so small relative to the distances between them. With no gas and dust clouds to interact with, there is nothing else to flatten the stars into a single plane of rotation. Ellipticals are described according to their degree of elongation—how much they deviate from a perfect sphere (see p.302)—but the largest galaxies are always very close to perfect spheres.

GIANT ELLIPTICAL

M87 is the giant elliptical at the heart of the nearby Virgo cluster. It is a type E1 or E0, almost perfectly spherical and containing roughly a trillion stars. At lower right, three smaller galaxies can be seen.

INTERMEDIATE GALAXY

DWARF ELLIPTICAL

M49 in the Virgo galaxy cluster is a large elliptical of type E4. With a diameter of about 160,000 light-years, it is classed by some astronomers as a giant elliptical, although its mass is much less than that of the true giants.

The Leo I galaxy is a nearby dwarf elliptical, and one of the few we can study closely. With so few stars, there must be a large amount of dark matter holding the galaxy together with its gravity.

B EY O N D TH E M I LK Y WAY

LENTICULAR GALAXIES

DUSTY LENTICULAR

Lying 25 million light-years away, At first glance, lenticular galaxies appear to be relatives of galaxy NGC 2787 is one of the ellipticals—they are dominated by a roughly spherical closest lenticular galaxies. Dust nucleus of old red and yellow stars. However, around this lanes can be seen silhouetted nucleus, these galaxies also have a disk of stars and gas. This against the nucleus, marking the plane of its disk. links them to spiral galaxies, and they are similar in overall size and general shape, although the nucleus is often elliptical orbits in considerably bigger than it would be in a spiral of similar the disk size.The overall shape is often described as that of a lens, which is the root of the name “lenticular.” The key chaotic orbits in the hub difference between lenticulars and spirals is that lenticulars have no spiral arms and little sign of star-forming activity in their disks. Without the bright blue star clusters that illuminate the disks of spirals, lenticulars are sometimes hard to tell apart from ellipticals. Those that are face-on may be indistinguishable from ellipticals and misclassified. An edge-on spiral galaxy with a large nucleus can equally be misclassified as lenticular, because at oblique angles spiral structure ORBITS IN LENTICULAR GALAXIES Stars in the nucleus of a lenticular is often invisible. Astronomers are galaxy follow orbits with no specific uncertain how lenticular galaxies form, plane, similar to those in an elliptical but they could be spiral galaxies that galaxy or a spiral nucleus. Gas and dust have lost most of their dust and gas. in the disk orbits in a more orderly plane.

TYPES OF GALAXY

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EXPLORING SPACE

IRREGULAR DWARF

The irregular dwarf galaxy NGC 4449 contains clusters of young bluish stars interspersed with dustier reddish regions of current star formation.

GALAXIES AT DIFFERENT WAVELENGTHS Radiation of different wavelengths can reveal hidden structures within galaxies. The hottest stars appear brightest in ultraviolet, while cool, diffuse gas may be visible only in infrared. By overlaying images from different spectral regions, astronomers build up a full picture of a galaxy. FROM ULTRAVIOLET TO INFRARED

These images of galaxy NGC 1512 increase in wavelength from left to right. Each wavelength is represented by a false color.

COMBINED IMAGE OF NGC 1512

FAR ULTRA– VIOLET

NEAR ULTRA– VIOLET

GREEN VISIBLE LIGHT

YELLOW VISIBLE LIGHT

NEAR INFRARED

MIDINFRARED

FAR INFRARED

IRREGULAR GALAXIES Not all galaxies fit into the scheme of spirals, ellipticals, and lenticulars. Some of these misfit galaxies are colliding with companions or being pulled out of shape by a neighbor’s gravity. These are usually classed under the catch-all term “peculiar” or “Pec.” Many more are true irregulars (type Irr). These galaxies typically contain a lot of gas, dust, and hot blue stars. In fact, many irregulars are “starburst” galaxies, with great waves of star formation sweeping through them. Irregulars frequently have vast, pink hydrogen-emission nebulae where star formation is taking place. Some irregulars show signs of structure—central bars and sometimes the beginnings of spiral arms. The Milky Way’s brightest companion galaxies, the Large and Small Magellanic Clouds (see pp.310–11), are typical irregular galaxies.

IRREGULAR STARBURST

M82 is an irregular starburst galaxy crossed with dark dust lanes. It is undergoing an intense period of star birth.

PECULIAR GALAXY EXPLORING SPACE

ASTRONOMY FROM THE SOUTH POLE

CENTRAL BLACK HOLES Many, if not all, galaxies have a dark region within their nucleus that seems strange by contrast with the outer parts. The fast orbits of stars near galactic nuclei suggest an enormous concentration of mass in a tiny volume at the center of most spiral and elliptical galaxies—often billions of Suns’ worth of material in a space little larger than the solar system. The only object that can reach such a density is a black hole (see p.26). Despite the tremendous gravity of this “supermassive” black hole, in most nearby galaxies the material has long since settled into steady orbits around it. With no material to absorb, the black hole remains dormant. When a gas cloud or other object comes too close, however, the black hole may awake, pulling in the stray material and heating it, producing radiation. The black hole may generate any type of radiation from low-energy radio waves to highenergy X-rays. In extreme cases called “active galaxies” (see pp.320–21), the radiation from the nucleus is the galaxy’s dominant feature.

HIDDEN SUPERMASSIVE BLACK HOLE

An X-ray image of galaxy M82 shows glowing hot gas and intense point sources of X-rays. These are probably stellar-mass black holes surrounding a central supermassive black hole.

BE Y ON D T HE M I L KY WAY

Some of the best Earth-based observations of galaxies come from an automated observatory at the South Pole. The AASTO project takes advantage of the dryness on the Antarctic Plateau—the driest place on Earth. With no water vapor in the atmosphere, nearinfrared light is not absorbed, so it reaches the ground unhindered.

NGC 4650A is a rare example of a polar-ring galaxy, perhaps created in a galactic collision. A blue-white star-forming ring, aligned with the poles, extends from the nucleus.

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GALAXY EVOLUTION

GALAXY EVOLUTION 22–23 The scale of the universe

THE PROCESSES BY WHICH DIFFERENT

types of galaxies form have puzzled astronomers for almost a century, 302–305 Types of galaxy but today a new generation of Active galaxies 320–21 telescopes, capable of studying Galaxy clusters 326–27 galaxies billions of light-years Galaxy superclusters 336–39 away, is finally resolving some key questions. Light from these remote galaxies left on its long journey to Earth when the universe was very young, so it can reveal the secrets of the early stages of galactic evolution. 54–55 Out of the darkness

THE DISTRIBUTION OF GALAXIES Astronomers can only ever see a “snapshot” of a brief moment in a galaxy’s long life story, so they have to build up a picture of galactic evolution by studying many individual galaxies. Such studies have revealed certain patterns, such as the fact that large elliptical galaxies are found only in substantial galaxy clusters. Changes in the type of galaxies seen at different distances—and therefore at different stages in cosmic history—can also reveal patterns in the way galaxies have developed. However, capturing the light of the most distant early galaxies is an enormous challenge, requiring techniques such as longexposure deep-field photography and the use of gravitational lensing. GRAVITATIONALLY LENSED GALAXIES

This image of a small area in the constellation Hydra was taken by the Herschel Space Observatory and reveals more than 6,000 galaxies. The white squares indicate distant galaxies that have been gravitationally lensed by foreground galaxies. These distant galaxies are brighter at the submillimeter wavengths detected by Herschel than at visiblelight wavelengths.

DUSTY LENTICULAR GALAXY

This image of the lenticular galaxy NGC 1316 in the constellation of Fornax was taken by the Hubble Space Telescope. It reveals a complex series of dust lanes and dust patches in the galaxy, indicating that it was formed from the merger of two galaxies rich in dust and gas.

EXPLORING SPACE

HERSCHEL

BE Y ON D T HE MI LK Y WAY

apparent position and distorted shape of multiple galaxy images

GRAVITATIONAL LENSING

The technique of gravitational lensing relies on the fact that the gravity of a massive object deflects light passing nearby—in effect, the object acts as a lens. In this way, a massive object, such as a galaxy cluster, situated light bent toward between Earth and a more observer by lens distant galaxy (or other object) can focus light from the distant galaxy onto Earth. This often produces multiple distorted images of the distant galaxy but also intensifies its light. observer on Earth

path of light without gravitational lensing

galaxy cluster acting as a gravitational lens

Launched in 2009, the European Space Agency’s Herschel Space Observatory is designed to observe the longest infrared wavelengths (the far infrared and submillimeter wavelengths on the boundary with radio waves). Its primary mirror is 11.5 ft (3.5 m) in diameter and its instruments are cooled to -456°F (-271°C), enabling it to map some of the coolest and most distant objects in the universe. secondary mirror sun shield primary mirror

actual position and shape of galaxy

THE HERSCHEL SPACE OBSERVATORY

GALAXY EVOLUTION

307

GALAXY FORMATION

GALAXIES

DARK MATTER

Until recently, there were two main theories of galaxy formation. The first was a “top-down” scenario, in which galaxies coalesced out of huge clouds of matter, eventually becoming dense enough to form stars within them. The second was a “bottom-up” scenario, in which small-scale structures formed first and gradually merged to create larger structures—galaxies. These two scenarios arose as a result of different ideas about the properties of dark matter (see p.27), specifically whether it is “hot” and fast-moving or “cold” and slow-moving. It now seems that the bottom-up model, with galaxy formation driven by the presence of relatively slow-moving cold dark matter (CDM), is correct. Computer simulations (such as the one shown below) suggest that in the early life of the universe, cold dark matter started to clump together in localized regions. These clumps acted as seeds, attracting yet more matter and eventually developing into protogalaxies and then mature galaxies. This happened in numerous localized regions throughout the universe, leading to the distribution of galaxies seen today.

2 1.0 BILLION YEARS OLD

3 4.7 BILLION YEARS OLD

4 13.6 BILLION YEARS OLD

Soon after the Big Bang, cold dark matter starts clumping together, attracting normal matter and forming irregular protogalaxies (bottom).

Matter continues to coalesce around the irregular protogalaxies, which begin to develop into larger galaxies (bottom).

Within a few billion years, dark matter has formed a weblike structure throughout the universe, and galaxies have become larger and more complex.

Close to the present day, the universe contains dense galaxy clusters and sparse voids, with highly evolved galaxies, such as ellipticals and spirals (bottom).

NGC 4621

NGC 4472

Since the 1990s, evidence has mounted to suggest that most, if not all, galaxies contain supermassive black holes at their centers, similar to the one at the center of our own Milky Way (see p.229). The masses of these black holes seem to be closely related to the overall sizes of the galaxies in which they lie, and a few galaxies even seem to contain two black holes in their cores. This suggests that black holes helped seed the formation of galaxies, and it also supports the “bottom-up” theory that larger galaxies are formed from mergers of smaller ones, with the central black holes ultimately joining together. However, the origin of these supermassive black holes is still unclear. Some theories suggest that the first black holes could have formed in the Big Bang or that they were created by the slow collapse of gas clouds around dark-matter cores. Another possibilility, which seems the most likely, is that they were formed by the death of an early generation of immense stars.

BE Y O ND TH E MI L KY WAY

THE ROLE OF BLACK HOLES

BLACK HOLES IN GIANT ELLIPTICAL GALAXIES

A comparison of the giant elliptical galaxies NGC 4621 (top) and NGC 4472 (bottom) reveals few stars in the core of NGC 4472 compared to the bright center of NGC 4621. It is thought that this “star deficit” is due to many of NGC 4472’s stars being ejected during the violent collision of NGC 4472 with another galaxy and the merger of their central supermassive black holes..

1 0.6 BILLION YEARS OLD

308

GALAXY EVOLUTION

GALAXY COLLISIONS Relative to their size, galaxies are quite closely packed together— although they are separated by distances of hundreds of thousands of light-years, galaxies themselves are typically tens of thousands of light-years across. Furthermore, the enormous gravity exerted by large galaxies and their tendency to form within large-scale clusters allow them to influence and attract one another. As a result, collisions and close encounters between galaxies are comparatively common. In 1966, US astronomer Halton Arp compiled the first catalog of galaxies that did not fit neatly into the common categories of spiral, irregular, and elliptical. With the benefit of more recent observations, it now seems that most of Arp’s unusual galaxies were the result of past collisions and interactions between galaxies. Even some apparently normal galaxies are now thought to have interacted with other galaxies in the past, and it is also clear that many large galaxies are “cannibals,” tearing apart and ultimately absorbing smaller galaxies that stray too close. However, during intergalactic collisions individual stars rarely collide, and it may take several billion years before the mutual gravity of colliding galaxies finally pulls together most of their material into a single combined cloud of stars. it

COLLIDING GALAXIES

Situated about 450 light-years from Earth in the constellation Hercules, two spiral galaxies (NGC 6050 and IC 1179, also collectively known as ARP 272 ) are colliding. Tidal forces in both galaxies are triggering enormous waves of star formation, manifested in the bright clusters around their spiral arms.

SEYFERT’S SEXTET

Despite its name, this group contains only five galaxies—the bright patch on the right is an unwinding spiral arm. Only four of the galaxies are at the same distance from Earth, about 190 million light-years away; the faceon spiral galaxy is about five times that distance. The four nearest galaxies are being distorted by gravitational forces between them.

THE SPLINTER GALAXY

Also known as the Knife Edge Galaxy or NGC 5907, this galaxy is an edge-on spiral that lies about 40 million light-years from Earth in the constellation Draco. It is surrounded by extraordinary looping trails of faint stars, nicknamed the “Ghost Stream,” which are thought to be the remnants of a smaller galaxy that has now been consumed by NGC 5907.

B EY O N D TH E M I LK Y WAY

COLLISIONS AND EVOLUTION The process of collision is now thought to play a key role in transforming galaxies from one type to another. In the early stages of a collision, stars that may have had relatively orderly orbits are pushed into highly elongated and tilted paths, and powerful shock waves passing through interstellar gas and dust generate tremendous bursts of new star formation. In the longer term, the remaining gas may become energized to such a degree that it can escape the galaxy’s gravity altogether, depriving it of the means to continue star formation. In this way, spiral and irregular galaxies can be transformed into ellipticals surrounded by clouds of hot gas, as seen in the central regions of many galaxy clusters. However, it has also been theorized that this process can be reversed, at least in the relatively short term. According to this theory, cold intergalactic gas is constantly drawn in by the galaxy’s gravity and can ultimately form a flattened disk in which star formation can begin again and spiral arms reform. If this theory is correct, then the rare lenticular galaxies mark an intermediate phase between elliptical and spiral galaxies. However, over time, merging spiral galaxies will form larger and larger ellipticals, while dwindling reserves of cold intergalactic gas will slow the regeneration of spiral galaxies.

SPIRALS IN COLLISION

The galaxy NGC 520 (also known as Arp 157) in the constellation Pisces is believed to be a pair of colliding spirals seen edge-on. The collision began about 300 million years ago, and the galaxies are now in the middle stages of merging: their disks have come together but their nuclei have not yet merged.

GALAXY EVOLUTION

309

TIDAL FORCES As two galaxies approach each other, their gravitational fields interact and can affect their shapes. For example, because the galaxies’ gravitational fields pull more strongly on the near side of each of the galaxies than on their more distant sides, their near sides become stretched out toward each other. Such gravitational distortion is greater on the less massive of the two galaxies, because of the stronger gravity of the other, more massive galaxy. However, the disks of even large spiral galaxies can be warped by the gravity of relatively small neighbors. When spirals collide with one another, one or more of the spiral arms may unwind, transforming into a long trail of stars that stretches out on the opposite side THE TADPOLE GALAXY from the collision. Among the This galaxy, in the constellation Draco, has best-known examples of these a tail that stretches for some 280,000 light“tidal tails” are the ones associated years and is thought to have formed when with the Tadpole Galaxy and the one of the spiral galaxy’s arms unwound in a close encounter with a smaller galaxy. Antennae Galaxies.

STARBURSTS

STARBIRTH IN THE ANTENNAE GALAXIES

This image of the Antennae Galaxies (NGC 4038 and 4039), which lie about 45 million light-years from Earth, reveals stars being born in huge starburst regions. The newborn stars are a brilliant white-blue and are surrounded by glowing pink emission nebulae.

BE Y ON D T HE M I L KY WAY

Intergalactic collisions can send immense shock waves through the galaxies involved, compressing large areas of interstellar gas and triggering enormous waves of star formation known as starbursts. During these events, starbirth occurs much faster than normal, giving rise to huge “super star clusters” that may (if they survive) evolve into globular clusters. Starbursts are commonly seen in direct collisions, such as that of the Antennae Galaxies, but can also occur in close encounters between galaxies, as seen in the Cigar Galaxy (see p.314) due to its close encounter with Bode’s Galaxy. Radiation from the numerous massive stars being formed, coupled with shock waves from supernovae as the heaviest stars rapidly age and explode, may blow gas and dust out of the galaxy, and it is this dispersion that may ultimately bring the starbursts to an end.

310

GALAXIES Astronomers are drawn naturally to the brightest, the most beautiful, and the most intriguing galaxies. However, of the 100 billion galaxies in the observable universe, only a minority are spectacular spirals and giant ellipticals. Astronomers are beginning to understand that most galaxies are relatively small and faint—diffuse balls and irregular clouds of stars. The faintest and most common galaxies are dwarf ellipticals, which are like oversized globular star BIG AND BRIGHT clusters of only a few million stars. These feeble galaxies are visible Spirals such as Bode’s Galaxy, M81, may be the most attractive type of galaxy, but they only if they lie nearby in intergalactic terms. The most brilliant are far from the most common. Making up are the giant ellipticals, which can be 20 times as luminous as less than 30 percent of all galaxies, they are the Milky Way. outnumbered by smaller, fainter galaxies. DWARF ELLIPTICAL GALAXY

SagDEG CATALOG NUMBER

None DISTANCE

88,000 light-years DIAMETER

10,000 light-years SAGITTARIUS

MAGNITUDE 7.6 for M54 star cluster in SagDEG

The Sagittarius Dwarf Elliptical Galaxy, often called SagDEG, was until recently our closest known

IRREGULAR GALAXY

Large Magellanic Cloud CATALOG NUMBER

None DISTANCE

179,000 light-years DIAMETER

20,000 light-years MAGNITUDE

0.1

DORADO

B EY ON D TH E M I LK Y WAY

The Large Magellanic Cloud (LMC) bears the name of 16th-century explorer Ferdinand Magellan (see panel, opposite). However, cultures native to the Southern Hemisphere have recognized its existence since prehistoric times. Like its smaller

RADIO MAP

This false-color radio image of the LMC is centered on the Tarantula Nebula. It shows intense radiation as red and black, indicating ionized hydrogen and star formation.

galactic neighbor. It was not found until 1994 and was supplanted only by the discovery of the even closer Canis Major Dwarf in 2003. SagDEG remained hidden for so long because, like all dwarf ellipticals, it is a very faint scattering of stars. It is also well disguised by its position behind the great Sagittarius star clouds that mark our galaxy’s center. SagDEG is small and obscure, but it has at least four orbiting globular clusters, which are brighter and more obvious. One of these, M54, was discovered by Charles Messier more than 200 years before the parent galaxy was found. counterpart, the Small Magellanic Cloud, the LMC appears from Earth to be a distinctive, isolated region of the Milky Way, some 10 degrees across, with its own areas of nebulosity and star clusters. The LMC is in fact an irregular galaxy, orbiting the Milky Way roughly once every 1.5 billion years on a path that brought it to within 120,000 light-years of our galaxy at its closest approach around 250 million years ago. Although the LMC is irregular and is being distorted by the gravity of the Milky Way, it shows some signs of basic structure. Many of its stars are concentrated in a central barlike nucleus, curved at one end. Some astronomers have likened the LMC to a barred spiral with just one arm. Like all irregular galaxies, the LMC is rich in gas, dust, and young stars, including some of the largest known regions of star birth. One such region is the magnificent Tarantula Nebula, also known as 30 Doradus. It is so brilliant that, if transported to the location of the Orion Nebula (see p.241)—only 1,500 lightyears away in the Milky Way—it would be bright enough to cast shadows on Earth at night. In recent times, the LMC was host to the only bright supernova since the invention of the telescope. Supernova 1987A (see p.266) was observed by astronomers around the world both during and after its explosion, and it has taught astronomers a lot about the final stages of the stellar life cycle.

STAR DENSITY

SagDEG’s existence came to light only when a survey of Sagittarius found regions of increased star density—the bright patches in this image.

SagDEG’s existence so close to our galaxy is a puzzle. It orbits the Milky Way in less than a billion years and so must have gone through several close encounters that should have ripped it apart and scattered its stars through the galactic

halo. It has survived only due to a large amount of dark matter, producing more gravity than SagDEG’s visible stars.

SUPERNOVA BUBBLE

This image shows a bubble of gas around the site of a supernova that exploded about 400 years ago in the LMC. The image is a composite from the Hubble Space Telescope and Chandra X-ray Observatory. Green and blue indicate hot, X-ray emitting material, and pink shows the visible gas shell shocked by the blast wave from the supernova explosion. The bubble is about 23 light-years across and is expanding at over 11 million mph (18 million kph).

TARANTULA NEBULA

Massive stars run through their entire life cycle in the Tarantula Nebula. This image shows a new open cluster, Hodge 301, whose biggest stars have already gone supernova. As the shock waves spread, they ripple the nearby gas clouds, triggering further star formation.

GALAXIES

311

EXPLORING SPACE

IRREGULAR GALAXY

MAGELLAN’S DISCOVERY

Small Magellanic Cloud CATALOG NUMBER

The southernmost sky was not visible to Europeans until they visited the Southern Hemisphere. The Portuguese explorer Ferdinand Magellan was among the first to do so during his round-the-world voyage of 1519–21. He was the first European to record two isolated patches of the Milky Way, which were later named after him.

NGC

292 DISTANCE

210,000 light-years DIAMETER

10,000 light-years MAGNITUDE

2.3

TUCANA

Like the Large Magellanic Cloud, the Small Magellanic Cloud (SMC) is an irregular galaxy in orbit around the Milky Way. It was in the SMC that Henrietta Leavitt discovered the Cepheid variable stars that were to unlock the secrets of the galactic distance scale (see pp.282, 356). Thanks to her discovery, astronomers know that the SMC is both more distant and genuinely smaller than the LMC, with around one-tenth of the larger cloud’s mass. Like the LMC, the small cloud is also undergoing intense star formation. Some astronomers argue that the SMC also shows signs of a central barlike structure, but the case

FERDINAND MAGELLAN

is far from proven. It has one known globular cluster in orbit, but the SMC lies deceptively close in the sky to one of the Milky Way’s largest globulars—47 Tucanae. Both the Magellanic Clouds are ultimately doomed to be torn to shreds and absorbed into our own galaxy. They have survived several close passes of the Milky Way, but now share their orbit with a trail of gas, dust, and stars torn away during

CLOUD OF STARS

The SMC forms a distinctive wedge-shaped cloud in southern skies. The pinkish areas in this optical photograph show the galaxy’s major star-forming regions.

previous encounters. This “Magellanic Stream” has allowed astronomers to trace and refine their models for the orbits of the clouds.

FLOCCULENT SPIRAL

SC SPIRAL GALAXY

Triangulum Galaxy CATALOG NUMBERS

M33, NGC 598 DISTANCE

3 million light-years DIAMETER

50,000 light-years MAGNITUDE

5.7

TRIANGULUM

After the Andromeda Galaxy and the Milky Way, the Triangulum Galaxy (M33) is the third major member of the Local Group of galaxies. It is slightly more distant than

M33 is an example of a flocculent spiral—a galaxy with arms that divide like split ends and separate into patches. The clumpy star clouds are thought to form due to localized changes in density.

NEBULA NGC 604 CLOUD DETAILS

In this image, the LMC’s central barlike nucleus appears as the bluish star cloud at the upper left, with the pink star-birth regions on the right.

This emission nebula’s gas glows as it is excited by ultraviolet light from a central star cluster. The stars are so massive and bright that they emit most of their light in ultraviolet, and so are not prominent in visible-light photographs such as this.

B EY O N D TH E MI L KY WAY

the larger and brighter Andromeda Galaxy (M31), and the two lie close to each other in the sky. M33 is affected by its larger neighbor’s gravity, and it may even be in a long, slow orbit around the giant Andromeda spiral. Seen from Earth, M33 is fainter and more diffuse than M31—partly because it is closer to face-on than edge-on, and partly because it really is less spectacular. However, the Triangulum Galaxy is more typical of spiral galaxies than its unusually bright companions. As with several Local Group galaxies, M33 is large and bright enough in the sky for its features to be cataloged, and several of them have NGC numbers. Most prominent is the starforming region NGC 604, the largest emission nebula known. At 1,500 light-years across, it dwarfs anything in our own galaxy.

312

Sb SPIRAL GALAXY

Andromeda Galaxy CATALOG NUMBERS

M31, NGC 224 DISTANCE

2.5 million light-years DIAMETER

250,000 light-years MAGNITUDE

3.4

ANDROMEDA

BE Y O ND T H E MI LK Y WAY

The Andromeda Galaxy (M31) is the closest major galaxy to the Milky Way and the largest member of the Local Group of galaxies. Its disk is twice as wide as our galaxy’s. M31’s brightness and size mean it has been studied for longer than any other galaxy. First identified as a “little cloud” by Persian astronomer Al-Sufi (see p.421) in around ad 964, it was for centuries assumed to be a nebula, at a similar distance to other objects in the sky. Improved telescopes revealed that this “nebula,” like many others, had a spiral structure. Some

GALAXY CORE

This X-ray image of the central area of M31 shows numerous point X-ray sources and a diffuse cloud of gas (in orange), which is being heated by shock waves from supernova explosions.

astronomers thought that M31 and other “spiral nebulae” might be solar systems in the process of formation, while others guessed correctly that they were independent systems of many stars. It was in the early 20th century that Edwin Hubble (see p.45) revealed the true nature of M31, at a stroke hugely increasing estimates of the size of the universe (see panel, opposite). Astronomers now know that M31, like the Milky Way, is a huge galaxy attended by a cluster of smaller orbiting galaxies, which occasionally fall inward under M31’s gravity and are torn apart. Despite being intensively studied, the Andromeda Galaxy still holds many mysteries, and it may not be

as typical a spiral galaxy as it appears. For example, despite its huge size, it appears to be less massive than the Milky Way, with a sparse halo of dark matter. Despite this, astrophysicists calculate that M31’s central black hole has the mass of 30 million Suns, almost ten times more than the Milky Way’s central black hole. The huge mass of M31’s black hole is surprising, because a galaxy’s black hole is thought generally to reflect the mass of its parent galaxy. Furthermore, studies at different wavelengths have revealed disruption in the galaxy’s disk, possibly caused by an encounter with one of its satellite galaxies in the past few million years. M31 and the Milky Way are moving toward each other, and they should collide and begin to coalesce in around 5 billion years. CENTRAL BLACK HOLE

This X-ray image of a small area of M31’s core shows its central black hole as a blue dot—it is cool and inactive compared to the galaxy’s other X-ray sources (yellow dots).

313 GALACTIC NEIGHBORS

Dark dust lanes are silhouetted against glowing gas and stars in this view of the Andromeda Galaxy and its two close companions, the dwarf elliptical galaxies M32 (upper left) and M110 (bottom).

INTERGALACTIC DISTANCE The study of M31 played a key role in the discovery that galaxies exist beyond our own. Although the spectra of galaxies suggested they shone with the light of countless stars, no one could measure their immense distance. In 1923, Edwin Hubble (see p.45) proved that M31 lay outside our galaxy. He found the true distance of M31 by calculating the luminosities of its Cepheid variable stars (see pp.282–83), and relating their true brightness to their apparent magnitude.

the same star at its brightest Cepheid variable V1 at its faintest

BE Y O ND TH E MI L KY WAY

EXPLORING SPACE

314

GALAXIES

Sb SPIRAL GALAXY

Bode’s Galaxy

core

CATALOG NUMBERS

M81, NGC 3031 DISTANCE

10.5 million light-years

X-RAY SOURCES

DIAMETER

95,000 light-years MAGNITUDE

6.9

URSA MAJOR

Bode’s Galaxy, also known as M81, is one of the brightest spiral galaxies visible from the Northern Hemisphere. It is the dominant member of a galaxy group lying near to the Local Group. The galaxy is named after Johann Elert Bode, a German astronomer who found it in 1774. Bode’s Galaxy has had a close encounter with M82, the Cigar Galaxy (see below), in the past few tens of CLUSTERS REVEALED

This combined visible and ultraviolet image shows the hottest and brightest star clusters (blue and white blobs), lying in the core and spiral arms.

A Chandra X-ray image shows a strong X-ray source at the galaxy’s core, surrounded by smaller sources, probably X-ray binary stars.

millions of years. The near miss created tidal forces that enhanced the density waves (see p.303) in M81. The rate of star birth around the density waves increased, highlighting the spiral arms. A long, straight dust lane along one side of the core could also have been created in the encounter. By measuring the Doppler shifts of light from either side of the core, astronomers have found that the outer regions rotate more slowly than in most galaxies. This suggests that M81 has little of the dark matter that creates higher rotation rates in other galaxies.

PERFECT SPIRAL

M81 is a beautifully symmetrical spiral galaxy, tilted at an angle to our line of sight. This Hubble view shows star clusters, dust, and gas clouds in its spiral arms.

Sb SPIRAL GALAXY

IRREGULAR DISK GALAXY

Black Eye Galaxy

Cigar Galaxy CATALOG NUMBERS

M82,

CATALOG NUMBERS

NGC 3034

M64, NGC 4826

DISTANCE

DISTANCE

12 million light-years

19 million light-years

DIAMETER

DIAMETER

51,000 light-years

40,000 light-years

BE Y ON D T HE MI LK Y WAY

MAGNITUDE

GAS STREAMERS

M82’s most spectacular features can be observed only at the radio wavelength emitted by ionized hydrogen, here represented as magenta. This wavelength reveals a huge envelope of gas above and below the core, blown out in long streamers by fierce radiation from the central star clusters.

8.9

MAGNITUDE

8.5

URSA MAJOR

COMA BERENICES

The brightest and most spectacular example of a “starburst galaxy,” the Cigar Galaxy (M82) is an irregularly shaped cloud of stars that looks like a cigar from Earth. It is undergoing a period of intense star birth as a result of a close encounter with Bode’s Galaxy (M81). The near miss has disrupted the galaxy’s center, creating the dark dust lanes that obscure much of the core and triggering the creation of many massive, brilliant star clusters in an area a few thousand lightyears across. At infrared wavelengths, M82 is the brightest galaxy in the sky, and it is also a strong radio source. The infrared light comes from disturbed gas and dust around the core.

This distinctive galaxy has a dark dust lane, running in front of its core, from which it gets its name. The dust lane is unusual because it arcs above the galaxy’s core in an orbit of its own. Because it has not yet settled into the plane of the galaxy’s rotation, it must have a recent origin and probably dates from the galaxy’s absorption of a smaller galaxy that strayed too close. Another bizarre feature of the Black Eye Galaxy is that its outer regions are rotating in the opposite direction of the inner regions. This could be another effect of the collision.

STARBURST GALAXY X-RAY VIEW cluster of active black holes

OPTICAL IMAGE

The intense activity in M82’s core is luminous at optical and X-ray wavelengths. The young stars illuminate the nebulae with visible light, while those that have rapidly completed their life cycle form active black holes, emitting X-rays.

M64’S CENTRAL REGION AND DUST LANE

GALAXIES LIGHT INTENSITY

Sc SPIRAL AND IRREGULAR GALAXIES

Plotting the intensity of light from different regions of M51 reveals the brightness of the two galactic cores (the twin peaks on the graph).

Whirlpool Galaxy CATALOG NUMBERS

M51,

NGC 5194, NGC 5195

NGC 5195

DISTANCE

NGC 5194

31 million light-years foreground star

DIAMETER

100,000 light-years MAGNITUDE

315

8.4

CANES VENATICI

Discovered by Charles Messier (see p.73) in 1773, the Whirlpool Galaxy is now known to be a pair of galaxies that is interacting—the brightest and clearest example of such a pair visible from Earth. The individual components are a spiral galaxy viewed face-on (NGC 5194) and a smaller irregular galaxy (NGC 5195). In visible light, the connection between them cannot be seen, but images at other wavelengths reveal an envelope of gas connecting the two. One effect of the interaction is to enhance the density wave in the larger galaxy, triggering increased star formation and making its spiral arms stand out very clearly. The Whirlpool was in fact the first “nebula” in which spiral structure was recognized, by William Parsons (see panel, right). The interaction has also triggered increased activity in the cores of both of the galaxies—NGC 5195 is

WILLIAM PARSONS William Parsons (1800-67) was an Irish nobleman who used his great wealth to build the largest telescope of his time and made the first detailed studies of nebulae. In 1845, he made detailed drawings and noticed the spiral structure of some “nebulae,” as galaxies were thought to be at the time. This was an important step to discovering that galaxies were not nebulae but separate star systems.

CONTRASTING PAIR

This infrared image, taken by the Spitzer Space Telescope, shows the Whirlpool Galaxy and its companion. The Whirlpool itself is rich in dust, which is colored red, while the companion is largely dust-free and appears blue.

undergoing a burst of star formation, which explains its unusual brightness, while NGC 5194’s core is also much brighter than expected. It is even classified by some astronomers as an active Seyfert galaxy (see p.320). The Whirlpool Galaxy is very bright despite its distance, indicating that it is

large and luminous—it is similar in size to the Milky Way, but brighter overall because of the large young star clusters in its spiral arms. It is thought to be the dominant member of a small group of galaxies, called simply the M51 group, which also includes the galaxy M63.

PARSONS’S SKETCH OF M51

This Hubble image combines data from different filters to reveal detail in M51, such as dark dust behind each spiral arm and bright pink regions of star birth.

BE Y O ND T HE M I L KY WAY

LUMINOUS WHIRLPOOL

316

GALAXIES RELATIVE RED SHIFT

SC SPIRAL GALAXY

Pinwheel Galaxy CATALOG NUMBERS

M101, NGC 5457 DISTANCE

27 million light-years

This computer image shows the red shift and blue shift of objects within M101, revealing its rotation. Yellow and red regions are moving away, green and blue parts are approaching.

DIAMETER

170,000 light-years MAGNITUDE

7.9

URSA MAJOR

Cataloged by Charles Messier (see p.73) as M101, the Pinwheel Galaxy is a bright, nearby spiral galaxy, but one that reveals its nature only when studied with powerful telescopes or seen on long-exposure photographs. Because it lies face-on to Earth, most of the Pinwheel’s light is spread out across its disk, and a casual glance reveals only the bright central core. Detailed photographs show that M101 has an extensive, though rather

lopsided, spiral-arm system, giving the appearance that the core is offset from the galaxy’s true center. M101 is one of the largest spirals known— its visible diameter is more than twice that of our own galaxy. Its large angular size in the sky (larger than a full moon) makes it one of the few galaxies whose individual regions can be isolated for study. ASYMMETRICAL DISK

M101’s lopsided shape is thought to be caused by uneven distribution of mass in the disk affecting the orbit of its stars.

DUST LANE

The thick dust lane around the Sombrero Galaxy is silhouetted against its bright disk in this Hubble Space Telescope image.

SA SPIRAL GALAXY

Sombrero Galaxy BE Y O ND T H E MI LK Y WAY

CATALOG NUMBERS

M104, NGC 4594 DISTANCE

50 million light-years DIAMETER

50,000 light-years MAGNITUDE

8.0

VIRGO

The dark dust lane and bulbous core of the Sombrero Galaxy (M104) give it a likeness to the traditional Mexican hat after which it is named. From Earth, we see the Sombrero Galaxy from six degrees above its equatorial plane—an ideal angle to provide a clear view of the core while also revealing the spiral arms. It is usually classified as an Sa or Sb spiral,

although its core is unusually large and bright. Another odd feature is the dense swarm of globular star clusters orbiting the galaxy. More than 2,000 have been counted—ten times more than orbit the Milky Way. In the galaxy’s core is a disk of bright material tilted relative to the galaxy’s plane. It is probably the accretion disk of a central supermassive black hole. X-ray emission from the region suggests some material is still being absorbed by the hole. M104 was a late addition to Messier’s catalog of celestial objects. He added it by hand to his copy of the catalog after discovering it in 1781. Several other astronomers also found it independently. One

COMBINED VIEW

This composite image shows the Sombrero at X-ray (blue), optical (green), and infrared (orange) wavelengths.

VESTO SLIPHER US astronomer Vesto Slipher (1875–1969) was one of the first to suggest that the universe is bigger than our galaxy. In 1912, at Lowell Observatory in Flagstaff, Arizona, he identified red-shifted lines in M104’s spectrum. The lines told him the galaxy was receding at 2.25 million mph (3.6 million km/h)—too fast for it to reside within the Milky Way.

of these was William Herschel, who was the first to note the dark dust lanes that are M104’s most distinctive feature. More recently, the Sombrero provided some of the first evidence for objects lying far beyond our own galaxy (see panel, below).

GALAXIES S0 LENTICULAR GALAXY

Spindle Galaxy CATALOG NUMBERS

M102 (not confirmed), NGC 5866 DISTANCE

40 million light-years DIAMETER

60,000 light-years DRACO

MAGNITUDE

9.9

The Spindle (NGC 5866) is an attractive galaxy orientated edge-on to observers on Earth. It is usually classified as a lenticular galaxy—a disk of stars, gas, and dust with a typical bulging core, but with no sign of true spiral arms. However, spiral structure is hard to detect in an edge-on galaxy. The Spindle Galaxy is the major member of the NGC 5866 Group, a small cluster of galaxies. Astronomers have measured the way these galaxies move and have found that the Spindle must contain an enormous mass of material—up to 1 billion solar masses, or 30 to 50 percent more than the Milky Way. The Spindle Galaxy could be the mysterious entry number 102 in Charles Messier’s catalog of astronomical features. Messier included the object at first without a location, then later gave coordinates that did not match any feasible object. Some believe that Messier had listed the Pinwheel Galaxy, M101, twice. More likely, however, is that M102 was the Spindle, and he added 5 degrees to his measurements in error. MASSIVE SPINDLE

From Earth we see the Spindle Galaxy edgeon, giving it a cigar-shaped appearance with a fine silhouetted dust lane.

DISRUPTED SPIRAL GALAXIES

Antennae Galaxies CATALOG NUMBERS

NGC 4038, NGC 4039 DISTANCE

63 million light-years 360,000 light-years (total) DIAMETER

MAGNITUDE

10.5

CORVUS

The Antennae Galaxies, NGC 4038 and 4039, are among the sky’s most spectacular interacting galaxies. Seen from Earth, they appear as a central bright double-knot of material, with two long streamers of stars stretching in opposite directions, resembling an insect’s antennae. However, powerful telescopes reveal that each streamer is in fact a spiral arm, uncurled from its parent galaxy by the tremendous gravitational forces of an intergalactic collision that began around 700 million years ago and continues today.

CATALOG NUMBERS

M60, NGC 4649 DISTANCE

58 million light-years DIAMETER

120,000 light-years MAGNITUDE

8.8

VIRGO

M60 is one of several giant elliptical galaxies in the Virgo galaxy cluster (see p.329), the central cluster in our own Local Supercluster of galaxies. The galaxy and its neighbor, M59, were discovered in 1779 by German astronomer Johann Köhler, who was observing a comet that passed close by. Charles Messier (see p.73) found them a few nights later, and added them to his catalog of objects that might confuse comet hunters. M60 is similar in diameter to many spiral galaxies but, as an E2 elliptical, it is very nearly spherical, containing a much

CLOSE NEIGHBORS

M60 lies very close to the spiral M59 (upper right), and the two galaxies are thought to be interacting. In a billion years, M60 may even swallow M59 entirely.

Turbulent dust clouds and brilliant star clusters appear in a Hubble view of the colliding Antennae Galaxies at right. The image above—a composite of a Hubble visible-light view with microwave observations from the Atacama Large Millimeter Array in Chile—reveals clouds of dense, cold gas (pink, red, and yellow areas) from which new stars are forming.

BE Y O ND TH E MI L KY WAY

A wide-field view of the Antennae taken from Earth reveals both the bright, distorted cores and the long, faint streamers formed by the disrupted spiral arms.

M60

larger volume. It probably has a mass of several trillion suns, and is orbited by thousands of globular clusters. Using the Hubble Space Telescope to measure the motions of M60’s stars, astronomers have discovered that a black hole of 2 billion solar masses lies at the galaxy’s heart.

The Antennae have been studied for what they can tell us about galaxy collisions. Detailed images of the central region show that it is lit by hundreds of bright, intense star clusters. These are thought to be forming as gas clouds in the galaxies become compressed by the collision, triggering starbursts (see the Cigar Galaxy, p.314). Astronomers can use the clusters’ redness to estimate their age—older clusters emit redder light because the brighter blue stars are the most massive and therefore the first to die.

CLOUDS AND CLUSTERS

THE BIGGER PICTURE

E2 ELLIPTICAL GALAXY

317

318

GALAXIES DISRUPTED SPIRAL GALAXY

ESO 510-G13 CATALOG NUMBER DISTANCE

ESO 510-G13

150 million light-years DIAMETER

105,000 light-years MAGNITUDE

13.3 HYDRA

SB0 BARRED SPIRAL GALAXY

Despite being referred to only by a number rather than a name (its long designation comes from the European Southern Observatory’s catalog), ESO 510-G13 is one of the most intriguing galaxies in the sky. It is an edge-on spiral with a clear dust lane marking its central plane. The dust lane has an obvious twist. The most obvious explanation for the kink is that ESO 510-G13 has had a close encounter or collision with another galaxy in its recent past. Some astronomers have suggested that

CATALOG NUMBER

CATALOG NUMBER

NGC 6782

NGC 4676

DISTANCE

DISTANCE

183 million light-years

300 million light-years

DIAMETER

DIAMETER

B EY ON D T HE M I LKY WAY

MAGNITUDE

300,000 light-years

12.7

MAGNITUDE

14.7

PAVO

COMA BERENICES

The Hubble Space Telescope imaged the apparently normal barred spiral galaxy NGC 6782 in 2001. Using ultraviolet detectors, it studied the pattern of the galaxy’s hottest material. The image (see below) showed, in pale blue, two rings of stars so brilliant and hot that they emit most of their light as ultraviolet. The inner ring lies in the galaxy’s bar and could have been ignited by tidal forces between the bar and the rest of the galaxy. The outer star ring is at the galaxy’s edge.

The object classified as NGC 4676 is in fact a pair of colliding galaxies— called the Mice because they appear to have white bodies and long, narrow tails. As with the Antennae Galaxies (see p.317), the long streamers are the result of the spiral arms “unwinding” during the collision—though in this case one of the arms lies edge-on to us and so appears to be long and straight, despite being strongly curved away from us. Knots of bright blue stars in the streamers and the main bodies of the galaxies show where bursts of star formation are taking place. Computer simulations of the collision (see panel, right) suggest that the galaxies are now separating after a closest approach 160 million years ago. HIDDEN EXTENT

ULTRAVIOLET STAR RINGS

Image processing allows astronomers to amplify faint light from the outlying parts of the Mice, revealing their true shape and extent.

WARPED DISK

The bright core of ESO 510-G13 silhouettes the galaxy’s warped dust lane in this image. The blue glow on the right is a huge area of bright young stars—evidence, perhaps, of a collision in the galaxy’s recent history.

SIMULATING GALAXY COLLISIONS

The Mice

82,000 light-years

gas than in the stars, so it is usually most obvious at radio wavelengths. Our near neighbor M31 (see pp.312– 13) has such a distortion, and the Milky Way seems to have one, too, perhaps caused by interaction with its own family of smaller neighbors.

EXPLORING SPACE

DISRUPTED SPIRAL GALAXIES

NGC 6782

the collision is still going on, and the dust lane is the “ghost” of a galaxy that ESO 510-G13 has swallowed—as seen in the active galaxy Centaurus A (see p.322). Alternatively, the disk might have been warped by the gravity of a nearby galaxy. The galaxy responsible might be a small neighbor or a more distant but larger member of the same group. As their techniques and instruments improve, astronomers are finding this kind of distortion is common in spirals, although it often shows up more in the distribution of

The great challenge for astronomers studying colliding galaxies is that they can only ever see one stage in a story that unfolds over millions of years. Fortunately, 0 MY today’s supercomputers can help to speed things up. By building “model” galaxies with simplified star clouds, gas, dust, and dark matter, then smashing them into each other in a computer, astronomers can measure how gravity affects the fate of the galaxies. SPIRAL COLLISION SIMULATION

This computer simulation shows two spiral galaxies interacting and merging to form a large, irregular galaxy. Time is measured in millions of years (My).

DESTINED TO UNITE

Although currently moving apart from a close encounter, the Mice are gravitationally locked together and doomed eventually to merge, perhaps resulting in the formation of a new giant elliptical galaxy.

400 MY 1,000 MY

650 MY

GALAXIES DISRUPTED SPIRAL GALAXY

Cartwheel Galaxy CATALOG NUMBER

ESO

350-G40 DISTANCE

500 million light-years DIAMETER

through each other at high speed while orientated at right angles to each other. The rotating density wave that is normally responsible for the spiral arms was disrupted in this case, resulting in the disappearance of the spiral structure. Meanwhile, a shock wave spread to the outer edge of the galaxy, creating a ring of vigorous star

formation. An inward-traveling shock wave is probably responsible for the core’s unusual “bull’s-eye” appearance. For years, most astronomers suspected that one of the Cartwheel’s two immediate neighbors was responsible for the collision. Both showed signs of being the culprit— a nearby small, blue galaxy has a

319

disrupted shape and vigorous star formation, while a yellow galaxy could have been stripped of its star-forming gas in the encounter. However, recent radio observations have shown a telltale stream of gas leading from the Cartwheel toward another small galaxy, a quarter of a million light-years away.

150,000 light-years MAGNITUDE

19.3

SCULPTOR

If the Cartwheel Galaxy looks unusual, it’s because it is the victim of an intergalactic “hit-and-run.” The Cartwheel was once a normal spiral galaxy. As we see the galaxy, it is recovering from a head-on collision with a smaller runaway galaxy many millions of years earlier in its history. Such events are rare in the cosmos— galactic collisions usually involve grazing encounters or a slow dance toward an eventual merger. The Cartwheel shows what happens when two galaxies pass CLOUDS IN THE CORE

So-called “comet clouds,” each a thousand light-years long, are found in the Cartwheel’s core. They are thought to arise as hot, fast-moving gas set in motion by the collision plows through denser, slower-moving matter.

SPIRAL REGENERATION

The “spokes” of the Cartwheel Galaxy (on the left) are the ghostly outlines of returning spiral arms.

RING GALAXY

LOW-SURFACE-BRIGHTNESS GALAXY

Hoag’s Object

Malin 1

CATALOG NUMBER

PGC

CATALOG NUMBER

54559

None

DISTANCE

DISTANCE

500 million light-years

1 billion light-years

DIAMETER

DIAMETER

120,000 light-years MAGNITUDE

600,000 light-years

15.0

MAGNITUDE

25.7

COMA BERENICES

Hoag’s Object is one of the most bizarre galaxies in the sky. Although its ring structure suggests parallels to the Cartwheel Galaxy (a spiral disrupted by a head-on collision, see above), there are no nearby galaxies that could have caused an impact. One of two theories might account for the shape of Hoag’s Object and that of similar ring galaxies. The galaxies may be members of an unusual class of spiral in which the two arms develop into a circle. Alternatively, they may be former elliptical galaxies that have each swallowed another galaxy, creating a surrounding ring of star-forming material.

Despite its dull appearance, Malin 1 is an extremely important galaxy. Discovered by accident in 1987, it is an enormous but faint spiral that is for some reason poor at forming stars. It seems that such low-surfacebrightness galaxies could account for up to half the galaxies in the universe, though Malin 1 is one of the largest of the type.

SEE-THROUGH GALAXY

The gap between Hoag’s Object’s core and its ring is truly transparent—a background galaxy can be seen through it near the top of this image. However, the gap could still contain large numbers of faint stars.

MALIN 1 IN A NEGATIVE IMAGE

BE Y O ND T HE M I L KY WAY

SERPENS

320

ACTIVE GALAXIES

ACTIVE GALAXIES

material blasted from the nucleus expands into a lobe as it is slowed by the intergalactic medium

MANY GALAXIES ACROSS THE UNIVERSE

28–31 Matter 34–37 Radiation 40–43 Space and time 226–29 The Milky Way 302–305 Types of galaxy 306–309 Galaxy evolution

show surprising features that mark them as out of the ordinary. Although there are several types of these strange galaxies, their unusual behavior can always be traced back to powerful activity in their nucleus—it seems that there is an underlying similarity between them, and for this reason they are often studied together under the term “active galaxies.”

WHAT ARE ACTIVE GALAXIES? jet of particles shooting from black hole’s magnetic pole star being ripped apart by intense gravity

location of black hole

torus of dust, typically 10 lightyears across jet expands into lobe thousands of light-years long

Astronomers think that the features of active galaxies are linked to their central giant black holes. Most, if not all, galaxies have black holes with the mass of many millions of suns, known as supermassive black holes, at their nuclei (see p.305), but most such black holes are dormant—all material in these galaxies is in a stable orbit around the black hole. In active galaxies, matter is still falling inward, and as it falls it is heated by intense gravity, generating a brilliant blast of radiation. As the black hole “engine” pulls matter in, the superheated material forms a spiraling accretion disk. The hot disk emits X-rays and other fierce, high-energy magnetic field line radiation. Around the outer edge of the electron disk, a dense torus (doughnut shape) photon of radioof dust and gas forms. The intense wavelength radiation magnetic field surrounding the black hole also catches some of the infalling material, firing it out as two narrow beams at the poles, at right angles to the plane of the spinning accretion disk accretion disk. These jets shine with of heated gas radio-wavelength radiation, due to the synchrotron mechanism (right). BLACK-HOLE ENGINE

SYNCHROTRON RADIATION

The black hole of an active galactic nucleus is surrounded by a bright accretion disk and an outer dust cloud. Jets of material flow outward from the black hole’s poles.

As electrons from the black-hole jets move through the black hole’s magnetic field, they are forced into spiral paths, releasing synchrotron radiation—a type of EM radiation that is most intense at long radio wavelengths.

B EY O N D TH E M I LK Y WAY

ACTIVE TYPES Astronomers distinguish between four major types of active galaxies. Each displays its own set of active features, and in each case these features are evidence of the violent activity at the nucleus. Radio galaxies are the most intense natural sources of radio waves in the sky. The emissions typically come from two huge lobes on either side of an apparently innocuous parent galaxy (and often linked to it by narrow jets). Seyfert galaxies are relatively normal spirals with a compact, luminous nucleus that may vary in brightness over just a few days. Quasars appear as starlike points of light that show similar but more extreme variability. Red-shifted lines in their spectra reveal that they are extremely distant galaxies—powerful modern telescopes can resolve them as galaxies with incredibly brilliant cores. They are more powerful and more distant cousins of the Seyfert galaxies. Finally, blazars (also known as BL Lacertae objects) are starlike variable points similar to quasars, but with no significant lines in their spectra. The standard model of the black-hole engine (above) can explain the major features of each type—how the galaxy appears depends on the intensity of its activity, and the angle at which we see it.

RADIO GALAXY

QUASAR

In a radio galaxy such as NGC 383, the central region of the nucleus is hidden by the edge-on dust ring, and observers on Earth see only the radio jets and lobes.

In quasars, Earthbound observers can see over the dust ring, and brilliant light from the nucleus and disk drowns out the light of the surrounding galaxy.

radio jet dust ring RADIO SOURCE 3C31 (RADIO GALAXY NGC 383)

BLAZAR 3C 279

QUASAR PG 0052+251

BLAZAR

SEYFERT GALAXY

Blazars are active galaxies aligned so that observers on Earth look straight down the blackhole jet onto the nucleus. The galaxy is hidden by the brilliant light, but radio lobes can sometimes be detected, as in blazar 3C 279.

In Seyfert galaxies such as M106, the nucleus and accretion disk are exposed to our view, as in a quasar, but the activity is weak.

SEYFERT GALAXY M106

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THE HISTORY OF ACTIVE GALAXIES

NUDGED BACK INTO LIFE

Optical images of Centaurus A clearly show the dark dust lane of a spiral colliding with this elliptical galaxy. The overlaid radio map shows the burst of activity—the jets and plumes—triggered by this event.

The distribution of different types of active galaxies in the universe provides clues about how they evolve. Quasars and blazars are never seen close to Earth. They are always faint and distant, with red shifts indicating that they lie billions of light-years from Earth—we are seeing them as they were in much earlier times. Radio and Seyfert galaxies, in contrast, are scattered throughout the nearby universe, and radio jets are linked to both spiral and elliptical galaxies. So what happened to the quasars and blazars? It seems likely that they represent a brief phase in a galaxy’s evolution, false-color soon after its birth. At this time, material in the central regions would radio image of jet of have had chaotic orbits, and the central black hole engine would have particles been fueled by a continuous supply of infalling stars, gas, and dust. As the black hole swept up the available matter, objects with stable orbits at a safe distance remained. Starved of fuel, the engine would have petered out, and the quasar became dormant—a normal galaxy such as the Milky Way. Today, such galaxies can dust lane become active again if they are involved in collisions (optical that send new material falling in toward the black image) hole. Many nearby radio and Seyfert galaxies show optical view of false-color evidence of recent collisions or close encounters, galaxy’s elliptical radio image of arrangement of stars and some of these galaxies are close enough for galaxy’s lobe infrared telescopes to image disk of the dust rings around their EXPLORING SPACE spiral galaxy cores directly (see p.323). jet of particles SUPERLUMINAL JETS However, levels of recent emitting radio waves activity are restrained— Year Some quasars and blazars appear to defy the laws even the most spectacular of physics. Image sequences, taken years apart, active nucleus of 1992 radio galaxies generate show jets of material blasting away from the galaxy, containing an active black hole little energy compared to nucleus, apparently traveling faster than the surrounded by a speed of light. This apparent motion is called quasars, while Seyferts 1994 bright accretion “superluminal.” In reality, it is an illusion, created are the feeblest type disk and a dust ring when jets traveling at very high speeds, of up to of active galaxy. 1996

ACTIVE GALAXY

This idealized active galaxy is a spiral with a bright nucleus, which hides an active black hole. From the black hole’s poles blast two jets of particles, leaving at close to light speed, only slowing and billowing out into lobes many thousands of light-years away, as the particles hit the intergalactic medium.

1998 20 40 60 80 Distance (light-years)

99 percent of the speed of light, happen to be pointing almost directly toward us. TIME-LAPSE SEQUENCE

These images show jet emissions from blazar 3C 279, taken at intervals of almost two years, and showing motion apparently five times the speed of light.

IS THE MILKY WAY ACTIVE?

GALACTIC CENTER

This near-infrared image, taken using the Very Large Telescope in Chile, shows the center of the Milky Way. By following the motions of its central stars over more than 16 years, astronomers were able to determine that the supermassive black hole at the core is about 4 million times as massive as the Sun.

ANTIMATTER FOUNTAIN

This gamma-ray image traces positrons (antielectrons) around the Milky Way. The horizontal feature is the plane of the Galaxy, with the fountain above it.

BE Y ON D T HE M I L KY WAY

The Milky Way galaxy, like any galaxy with a central black hole, has the potential to be active, and there is intriguing evidence that it might have burst into activity in the recent past. In 1997, scientists discovered a huge cloud of gamma-ray emission above the galactic center. The radiation has a distinctive frequency, suggesting it is the result of electrons encountering positrons—their antimatter equivalent (see p.31)—and annihilating in a burst of energy. The positrons might have been generated by activity at the core— perhaps an infall of matter into the black hole— and are now meeting scattered electrons in the outer galaxy and mutually annihilating to produce the distinctive glow. Since the clouds lie just 3,000 light-years from the galactic center, the activity must have occurred recently.

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ACTIVE GALAXIES There are no simple rules governing the appearance of active galaxies. Some have a disrupted structure, seen either in visible light or at other wavelengths, while others appear normal at first, but radiate unusually large amounts of energy at certain wavelengths. In fact, the majority of galaxies show activity of one kind or another. However, a smaller proportion of galaxies have particularly active nuclei, powered by matter spiraling into their central black hole. These include Seyfert galaxies, radio galaxies, quasars, and blazars. The vast JET FROM AN ACTIVE GALAXY Pictured in radio waves and false colors, majority of known active galaxies are distant quasars. Objects lying this jet of particles blasted from the core nearer to the Milky Way, although less spectacularly violent, are at of the galaxy M87 is a typical feature of least close enough for astronomers to study in detail. active galaxies with black-hole engines. TYPE-II SEYFERT GALAXY

Circinus Galaxy CATALOG NUMBER

ESO 97-G13 SHAPE

Sb spiral

DISTANCE

13 million light-years DIAMETER

37,000 light-years CIRCINUS

MAGNITUDE

11.0

Although it is one of the nearest active galaxies to Earth, the spiral galaxy in Circinus went undiscovered until just a few decades ago. It remained hidden

for so long partly because it lies just 4 degrees below the plane of the Milky Way and is obscured by star clouds. The full extent of the Circinus Galaxy’s extraordinary nature was revealed only when it was observed by the Hubble Space Telescope in 1999. The galaxy is a Seyfert (see p.320)—a spiral with an unusually bright, compact region at its core, thought to result from material slowly drifting onto a massive central black hole. Hubble’s infrared camera revealed how the galaxy’s gas is concentrated in a central ring, just 250 light-years in diameter, around the black hole. Also apparent is a loose outer ring in the plane of

the galaxy, around 1,300 lightyears across, where great bursts of star formation are occurring. Finally, Hubble showed a coneshaped cloud billowing above the plane of the galaxy. This is matter ejected by the magnetic fields of the black hole and glows as it is heated by the ultraviolet radiation from the nucleus. CONE OF MATTER

The pinkish-white region near the core of the Circinus Galaxy shows where matter is being flung out, in a cone shape, from the central black hole into the gas cloud above the galaxy.

COMPOSITE VIEW

Centaurus A has been imaged at various wavelengths (left and below). The image at far left is a composite at optical, microwave, and X-ray wavelengths. RADIO CONTINUUM

RADIO (21-CM WAVELENGTH)

jet

OPTICAL WAVELENGTHS

BE Y ON D T HE MI LK Y WAY

DUSTY DISK

This Hubble Space Telescope closeup of Centaurus A (right) reveals dark interstellar dust, glowing orange gas clouds, and brilliant blue star clusters formed in the collision between two galaxies.

RADIO GALAXY

Centaurus A CATALOG NUMBER

NGC 5128 SHAPE

Peculiar elliptical

DISTANCE

15 million light-years DIAMETER

80,000 light-years CENTAURUS

MAGNITUDE

7.0

A ball of old yellow stars, NGC 5128 shows some features typical of an elliptical galaxy, but its most striking aspect is the dark dust lane that cuts across it, bisecting the uniform glow of stars with a ragged silhouette. What is more, the galaxy is at the center of a pair of vast radio lobes, 1 million light-years across. The name of this radio source, Centaurus A, is now the most widely used name for the galaxy itself. Astronomers have studied Centaurus A in detail at a range of

wavelengths. The Hubble Space Telescope looked through the dust lanes with its infrared camera and found a huge accretion disk at the center—a sure sign of an active black hole pulling in matter at Centaurus A’s core. It is now generally agreed that NGC 5128 is an elliptical galaxy absorbing a spiral. The ghost of the spiral is shown by the dust lane and by the bright star clusters that stud it—perhaps generated by shock waves as the two galaxies merge.

X-RAY WAVELENGTHS

ACTIVE GALAXIES RADIO GALAXY

M87 CATALOG NUMBERS

M87, NGC 4486 E1 giant elliptical

SHAPE

DISTANCE

60 million light-years DIAMETER

VIRGO

120,000 light-years MAGNITUDE

8.6

Lying at the heart of the Virgo galaxy cluster (see p.329), M87 is the closest example of a giant elliptical galaxy—a GALACTIC ERUPTION

The black hole at M87’s center is producing jets of energetic particles that are rising through the surrounding cooler gas in a similar way to gas erupting from a volcano on Earth.

class of galaxy often found at the cores old galaxy clusters. This huge ball of stars seems to have a diameter roughly equivalent to that of the Milky Way, but, because its stars are distributed across its spherical structure, it contains many more stars—probably several trillion. Long-exposure photographs have revealed that the galaxy also has an extensive halo of more loosely scattered stars, extending well beyond the central region in a more elongated shape. The galaxy also has an unrivaled collection of globular star clusters in orbit—some astronomers estimate as many as 15,000 such groups. What is more, M87 is an active galaxy—its location coincides with the Virgo A radio source, and with a strong source of X-rays. There is even a sign of this activity that is visible at optical wavelengths, in the form of a long, narrow jet of material being blasted from its interior.

323

TYPE-II SEYFERT GALAXY

CARL SEYFERT

Fried Egg Galaxy CATALOG NUMBER

NGC

7742 SHAPE

Sb spiral

DISTANCE

72 million light-years DIAMETER

36,000 light-years PEGASUS

MAGNITUDE

11.6

The small spiral galaxy NGC 7742 resembles a fried egg because of the intense yellow glow from its core. The core is much brighter than is usual for a galaxy of this size, because this is a Seyfert galaxy, with a moderately active core. Seyferts emit radiation across a broad band of wavelengths— NGC 7742 is a Type-II—a galaxy that is brightest in infrared light.

US astronomer Carl Seyfert (1911– 60) was the son of a pharmacist from Cleveland, Ohio. He studied at Harvard and went on to work at McDonald Observatory, then at Mount Wilson in California. It was here that he first identified the class of galaxies with unusually bright nuclei that bear his name (see p.320). In 1951, he also discovered Seyfert’s Sextet, an interesting, compact cluster of galaxies (see p.329).

energetic radio-emitting particles cooler gas

SEYFERT’S OBSERVATORY

supermassive black hole CELESTIAL EGG

RADIO GALAXY

NGC 4261 CATALOG NUMBER

NGC 4261 SHAPE

E1 elliptical

DISTANCE

100 million light-years DIAMETER

60,000 light-years VIRGO

MAGNITUDE

10.3

The elliptical galaxy NGC 4261 lies at the center of two great lobes of radio emission measuring 150,000 light-years from tip to tip. In many ways a typical radio galaxy, it is also one of the few active elliptical galaxies to have revealed its internal structure to astronomers. Infrared images from the Hubble Space Telescope pierced the obscuring clouds of stars to reveal an unexpectedly dense disk of dusty material, apparently spiraling onto the galaxy’s central black hole. Most elliptical galaxies are thought to be relatively dust-free, so where did the

material in NGC 4261 come from? The most likely answer is that the elliptical galaxy has merged with a spiral in its relatively recent history. The spiral’s individual stars have now become indistinguishable from the stars that were originally part of the elliptical galaxy, but the ghostly outline of the galaxy’s gas and dust remains.

At Nashville, Seyfert found time to give public lectures as well as raising support and supervising the construction of the Arthur J. Dyer Observatory (above).

TYPE-I SEYFERT GALAXY

NGC 5548 CATALOG NUMBER

NGC 5548 SHAPE

Sb spiral

DISTANCE

220 million light-years DIAMETER

DUST WHIRLPOOL

The Hubble Space Telescope’s close-up image of the core reveals a dusty spiral of matter within a ring of glowing outer clouds. A distinct cone shows where matter is being flung off from the active galactic nucleus into the radio lobes.

100,000 light-years BOÖTES

MAGNITUDE

HUBBLE IMAGE OF NGC 5548

BE Y O ND T HE M I L KY WAY

NGC 5548 is a Type-I Seyfert galaxy; that is, a Seyfert that emits more ultraviolet and X-ray radiation than visible light. Like all Seyferts, it has a bright, compact core, but, unlike the Fried Egg Galaxy (see above), its core is an intense blue-white. Using the Chandra X-ray telescope, astronomers have detected an envelope of warm gas expanding around the core. The gas eventually forms two lobes of weak radio emission around the galaxy.

RADIATING PLUMES

Combining optical and radio images of NGC 4261 reveals its full extent. The visible part of the galaxy is the white blob in the center, while the orange plumes mark the radio-emitting regions.

10.5

324 RADIO GALAXY

NGC 1275 CATALOG NUMBER

NGC 1275 Elliptical and distorted spiral

SHAPE

DISTANCE

235 million light-years DIAMETER

PERSEUS

70,000 light-years MAGNITUDE

ATYPICAL ELLIPTICAL GALAXY

CLUSTERS IN THE NUCLEUS

NGC 1275 is unusual for an elliptical galaxy in having a Seyfert-like core. The dark dust lanes are the remains of a now-disrupted separate spiral galaxy in front of NGC 1275.

The core of NGC 1275 offers clues to the origin of globular clusters—numerous globular-like clusters are found here, but they are composed of young blue, rather than old yellow stars.

11.6

Despite being cataloged as a Seyfert galaxy by Carl Seyfert himself (see p.323), NGC 1275 has remained a mystery. Recent observations have shown that there are two objects— one in front of the other. A ghostly spiral galaxy, revealed by its bright blue star clusters, is responsible for the dust lanes that cross the bright central region, but this brighter region is in fact a separate galaxy. Despite its Seyfert-like core, it is an elliptical, not a spiral. This galactic giant lies at the heart of the Perseus galaxy cluster, and the foreground spiral is racing toward it at 6.7 million mph (10.8 million km/h), its structure already disrupted by the elliptical’s gravity. Adding to the complexity, the elliptical galaxy is also a radio source, and some astronomers have argued that it shows blazar-like activity (see BL Lacertae, opposite). Whatever the details, NGC 1275 displays many of the typical features of an active galactic nucleus.

RADIO GALAXY

Cygnus A CATALOG NUMBER

3C 405 SHAPE

Pec (peculiar)

DISTANCE

600 million light-years DIAMETER

CYGNUS

120,000 light-years (excluding radio lobes)

B EY ON D TH E M I LK Y WAY

MAGNITUDE

15.0

The most spectacular and powerful radio galaxy in the nearby universe, Cygnus A was discovered as soon as radio telescopes began operating in the 1950s. It features two huge lobes of material emitting radio waves. The lobes are visibly linked to their origin at the heart of a faint, central, elliptical galaxy by two long, narrow jets. From lobe to lobe, the entire structure extends over half a million light-years. Despite its prominence in the radio sky, mysteries still surround Cygnus A, largely because of its great remoteness. Early observations led astronomers to believe the central galaxy was in fact a pair of colliding galaxies. Hubble Space Telescope images suggested a resemblance to NGC 5128, the Centaurus A galaxy

(see p.322), which is thought to be an elliptical galaxy that has recently swallowed a spiral. Recent detection of a large cloud of red-shifted gas moving through the Cygnus A galaxy suggests that a collision may indeed be the root cause of the activity. Astronomers have also argued about the origin of the “hot spots,” where the radio lobes glow brightest

at either end. Studies by the Chandra X-ray telescope have shown that Cygnus A lies at the center of a cloud of hot but sparse gas. The jets have blown out a football-shaped cavity in the gas so vast that it dwarfs the central galaxy. Tendrils of gas, which are emitting X-rays and radio waves, are also falling back down through the cavity onto the poles of the galaxy,

LOBES EMITTING RADIO WAVES

This radio map of Cygnus A shows the galaxy’s extremely narrow jets blasting from its core, the hot spots at the end its radio lobes, and the tendrils of hot gas falling back toward the central galaxy.

drawn by its gravitational pull. The hot spots are apparently created where the outward blast of the jets collides with the hot gas falling inward.

ACTIVE GALAXIES BLAZAR (BL LAC OBJECT)

BL Lacertae CATALOG NUMBER

BL Lac SHAPE

Elliptical

DISTANCE

1 billion light-years DIAMETER

Unknown LACERTA

MAGNITUDE

12.4–17.2

BL Lacertae (BL Lac for short) was first cataloged as an irregular variable star by German astronomer Cuno Hoffmeister in the 1920s. Since then, astronomers’ understanding of the object has

changed. For a variable star, it was very mysterious, showing rapid but completely unpredictable variations. At the same time, it displayed a totally featureless spectrum—it had neither the dark absorption lines seen in stars, nor the bright emission lines found in galaxies (see p.35). It was not until 1969, when BL Lac was found to be a strong radio source, that astronomers realized it might be a new type of active galaxy. Today it is seen as the founder member of a class of active galaxies called blazars or BL Lac objects. Blazars show many similarities to quasars but also some differences, most notably their featureless spectra. The mystery of BL Lac was solved in the 1970s, when two astronomers blocked out or “occulted” BL Lac’s bright core to study its surroundings. This revealed that it was embedded in a faint elliptical galaxy, whose light was normally drowned out. Redshifted lines in the spectrum of this galaxy confirmed BL Lac’s great distance (see p.44). Today, blazars are accepted as rare cases in which Earth’s position happens to align directly with the jet of material blasting out of an active galactic nucleus, with no obscuring material in the way. MAP OF A BLAZAR

This radio map of BL Lacertae shows the intensity of radiation (contour lines) and also its polarization (color)—an indication of magnetic field strength. The red object at the top is the galaxy’s nucleus, while the lower regions are parts of a radio jet.

QUASAR

PKS 2349 CATALOG NUMBER

PKS 2349 SHAPE

1.5 billion light-years DIAMETER

Unknown PISCES

MAGNITUDE

15.3

The Hubble Space Telescope offered astronomers an unprecedented chance to study quasars in detail during the 1990s. One of their most intriguing subjects was the otherwise undistinguished quasar PKS 2349 (referred to by its designation in the catalog of the Australian Parkes radio telescope). For the first time, astronomers were able to see the faint host galaxies surrounding

In Hubble’s image of PKS 2349, the quasar is the bright central object, the companion galaxy is the smaller bright region above it, and the supposed host galaxy is the fainter ring extending from the quasar.

FIRST QUASAR

3C 48

3C 273 CATALOG NUMBERS

CATALOG NUMBERS

3C 273, PKS 1226+02

3C 48, PKS 0134+029

SHAPE

E4 elliptical

SHAPE

SB interacting

DISTANCE

DISTANCE

2.1 billion light-years

2.8 billion light-years

160,000 lightyears (excluding jet)

DIAMETER

DIAMETER

MAGNITUDE

12.8

the lines could have been formed by hydrogen, oxygen, and magnesium if the light was heavily red-shifted and its source was racing away from us at 16 percent of the speed of light, or 107 million mph (173 million km/h). We now know that the object is not a star, but a distant active galaxy.

RADIO JET

An enormous jet of particles, 100,000 light-years long, streams out from the center of 3C 273. As the particles move away from the core (the white square), their energy diminishes, as shown in this image by the transition from blue (indicating X-rays) to red (infrared radiation).

TRIANGULUM

MAGNITUDE

16.2

The radio source 3C 48 has a unique place in the history of the study of active galaxies. It was detected in the 1950s, and in 1960 Allan Sandage (see panel, below) confirmed that it coincided with a faint, blue, starlike object. The object’s spectrum revealed strange emission lines (see p.35) that

ALLAN SANDAGE Beginning his astronomical career as a student under Edwin Hubble (see p.45), Allan Sandage (1926– 2010) has had a great influence on our understanding of the universe’s evolution. Sandage’s studies have focused on detecting Cepheid variable stars in distant galaxies, for use in measuring cosmological expansion. His many quasar discoveries were a natural offshoot from his studies of deep space.

At first, 3C 48 is indistinguishable from foreground stars. It was only its unpredictable variability and radio emission that marked it out as something special.

could not have been emitted by any known element. Studies of similar lines in the optical counterpart of 3C 273 (left) suggested that the lines of 3C 48 were hydrogen lines with a huge red shift, suggesting the object was extremely distant and receding at great speed. 3C 48 was therefore the first quasi-stellar object, or quasar, to be discovered.

B EY O N D TH E MI L KY WAY

The brightest quasar in the sky, 3C 273 was the second to be discovered. The existence of this radio source was already known when, in 1963, Australian astronomer Cyril Hazard used an occultation by the Moon (see p.69) to precisely establish its position, linking the radio source to what appeared to be an irregular variable star. The star’s spectrum had a forest of unidentifiable dark emission lines (see p.35). Astronomers finally realized that

100,000 light-years

HOST GALAXY

By blocking the light from 3C 273’s nucleus, the Hubble Space Telescope was able to photograph detail (above) in the fainter surrounding galaxy, including traces of a spiral structure and a dust lane.

quasars, as well as other galaxies close to the quasars. The images showed that in many cases quasars do not just sit at the centers of their host galaxies, but are involved in violent interactions with neighboring galaxies and other quasars. PKS 2349 was referred to as a “smoking gun” because it showed these interactions so clearly. The quasar is surrounded by a ring of faint material that may mark the outline of its host galaxy—though, if so, the quasar itself is remarkably “offcenter.” A small companion galaxy, about the size of the Large Magellanic Cloud (see p.310), also lies nearby and seems doomed to collide with the quasar itself.

QUASAR CLOSE-UP

QUASAR

QUASAR

VIRGO

Disrupted

DISTANCE

325

326

GALAXY CLUSTERS

GALAXY CLUSTERS 22–23 The scale of the universe

DENSE CLUSTER

GALAXIES ARE NATURALLY GREGARIOUS.

Pulled together by their enormous gravity, they cluster tightly, sometimes orbiting one 38–39 Gravity, motion, and orbits another, often colliding. As galaxies slowly 40–43 Space and time move within a cluster, the cluster’s 44–45 Expanding space structure changes. The evolution of 302–305 Types of galaxy clusters can tell astronomers about dark matter, and clusters can even be used as cosmic “lenses” to peer back into the early universe.

The massive galaxy cluster Abell 1689 lies 2.2 billion light-years away. The yellow elliptical galaxies are surrounded by arcs of light, which are images of more distant galaxies distorted by the cluster’s gravitational lensing.

24–27 Celestial objects

TYPES OF CLUSTERS Some galaxy clusters are sparse, loose collections of galaxies. The smallest clusters are usually termed “groups.” The Local Group (see p.328), of which the Milky Way is a member, is one such cluster. Other clusters, such as the nearby Virgo Cluster (see p.329), are denser, containing many hundreds of galaxies in a chaotic distribution. Yet other clusters, such as the Coma Cluster (see p.332), are even more dense, with galaxies settled into a neat, spherical pattern around a center dominated by giant elliptical galaxies. Although clusters differ in density, the volume of space they occupy is generally the same—a few million light-years across. Not all galaxies exist in clusters—there are more isolated “field galaxies” than there are cluster galaxies. Some galaxy types do not exist outside clusters, however. Giant ellipticals (see p.304) always lie near the center of large clusters, as do vast, diffuse cD galaxies (below right). The most numerous cluster components may be invisible, including faint, diffuse dwarf elliptical galaxies and proposed “dark galaxies.” A dark galaxy would consist of hydrogen gas and material too thin to condense and ignite stars. The first such galaxy Andromeda Galaxy (M31) may have been found, in the Virgo Cluster, in early 2005. SPARSE CLUSTER

B EY O N D TH E M I LK Y WAY

This sparse cluster, or group, of galaxies is in fact the Local Group, containing the Milky Way and its galactic neighbors. Most of the galaxies are orbiting Milky Way either the Milky Way or the Andromeda Galaxy (M31).

cD GALAXY dense core of cluster containing many large galaxies

IDEAL DENSE CLUSTER

A dense cluster occupies the same volume as a sparse cluster such as the Local Group, but the galaxies are mainly elliptical and have a roughly spherical distribution around the cluster’s center.

DWARF ELLIPTICAL

Most galaxies in the Local Group, including the Sculptor Dwarf, are dwarf ellipticals. They are invisible in distant clusters, but must be present.

cD galaxies are similar to giant ellipticals but have extensive, sparse outer haloes of stars. They sometimes have hints of multiple cores, suggesting the merger of several smaller ellipticals. NGC 4889 (left) is a cD galaxy at the heart of the dense Coma Cluster.

GALAXY CLUSTERS ABELL 2029

This visible-light image of Abell 2029 shows that it is an old, regular, spherical cluster full of elliptical galaxies.

327

THE INTERGALACTIC MEDIUM Astronomers can estimate the overall mass of a galaxy cluster from the way in which its galaxies are moving, but also through the phenomenon of gravitational lensing—an effect of general relativity (see pp.42–43). When a compact cluster lies in front of more distant galaxies, its mass bends the light passing close to it and deflects distorted images of the distant galaxies toward Earth. By measuring the strength of this effect, it is possible to measure the mass of the cluster and model how it is distributed. Galaxy clusters contain far more mass than the visible galaxies can account for, and most of it is in the matter that permeates the space between galaxies. This intergalactic medium is distributed around the cluster’s center, rather than around the galaxies. X-ray satellites such as Chandra have revealed the nature of part of this material—large galaxy clusters often contain huge clouds of INTERGALACTIC GAS An X-ray image of cluster Abell sparse, hot gas, glowing at X-ray wavelengths. Most is hydrogen, but 2029 shows the hot gas cloud heavier elements are present. It is thought to originate in the cluster around its center. If not for the galaxies, and to be stripped away during encounters and collisions. gravity of the cluster’s dark Most of a cluster’s mass is not gas, however, but dark matter. matter, this gas would escape. path of light without gravitational lensing light bent toward observer by lens

apparent position and distorted shape of multiple galaxy images

GRAVITATIONAL LENSING

Light leaves a distant galaxy in all directions. When it passes close to a massive cluster of galaxies, it is deflected from its path, due to the way mass distorts space. Light paths arrive at Earth apparently from different directions, creating multiple, distorted images of the galaxy.

actual position and shape of galaxy

PERFECT ARC

This striking example of lensing is created by the cluster CL-2244-02. The lensed galaxy, unlike the cluster galaxies, is blue, so it must be a spiral or an irregular.

galaxy cluster acting as a gravitational lens

CLUSTER EVOLUTION

The central regions of the Virgo Cluster (above) and the Coma Cluster (below) show the difference between an irregular and a more spherical (relaxed) pattern of galaxies.

VIOLENT MERGER

Cluster Abell 400’s core (left) shows two galaxies merging to form a giant elliptical. Radio images (below) reveal that both are active galaxies. Such a merger is typical of those that shape galaxy clusters.

B EY O N D TH E MI L KY WAY

IRREGULAR AND RELAXED CLUSTERS

Astronomers have built a picture of cluster development that complements their models of galaxy evolution (see pp.306–309). According to their thinking, galaxy clusters start as loose collections of gas-rich spirals, irregulars, and small ellipticals. Because of their proximity and huge gravity, the spirals tend to merge, regenerating as spirals or forming ellipticals. Each interaction drives off more of the galaxies’ free gas into the intergalactic medium. The high temperature and speed of atoms in this medium prevents their recapture by the cluster’s galaxies. At this stage, the cluster is irregular, or “unrelaxed,” and the pattern of galaxies and intergalactic gas is irregular and chaotic. However, as galaxies swing around each other, their random motions are eliminated and they settle into a stable, spherical, “relaxed” distribution around the cluster’s center. Eventually, even the largest elliptical galaxies begin to merge, forming giant ellipticals and cD galaxies. The hot gas, freed from ties to individual galaxies, sinks into the center of the cluster, where it lies evenly around the cluster’s major elliptical galaxies. What remains is an old, spherical, relaxed cluster full of ellipticals.

observer in the Milky Way

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GALAXY CLUSTERS The shape and size of galaxy clusters are thought to be linked to their evolution. Clusters range from small groups comprising young, gas-rich irregular and spiral galaxies, to highly evolved clusters dominated by giant ellipticals, with a central cloud of gas so hot that it emits X-rays. Astronomers can study details in nearby clusters that are too faint to see in distant clusters. Earth’s neighboring clusters do not offer STEPHAN’S QUINTET a spectacle to stargazers, however, because clusters are so This elegant group of five galaxies shows that clusters are constantly changing—two vast that their members are widely scattered across the sky. of its spiral galaxies are colliding, while a To appreciate clusters in a single picture, it is necessary to third is being distorted by their gravity and peer tens of millions of light-years into deep space. is doomed to collide with them one day. Andromeda Galaxy, M31

IRREGULAR CLUSTER

Local Group DISTANCE

0–5 million light-years NUMBER OF GALAXIES

46

BRIGHTEST MEMBERS

Milky Way; M31 (magnitude 3.5) ANDROMEDA AND TRIANGULUM

Triangulum Galaxy, M33

LOCAL GROUP MEMBERS

Since Earth is in the midst of the Local Group, the galaxies are scattered around the sky. However, two large members, M33 and M31, are near enough in the sky to appear in the same frame.

The Local Group is the small galaxy cluster of which the Milky Way is a member. From Earth, its members appear dispersed throughout the sky, but some of its galaxies are grouped in the constellations of Andromeda and Triangulum. In space, the core of the group comprises about 30 members in a region just over 3 million lightyears across. It is dominated by the Andromeda Galaxy (M31; see pp.312– 313), and the Milky Way. Most of the smaller galaxies orbit close to one or

the other of these large spirals. The third large spiral in the group, M33 (see p.311), may also be trapped in a long orbit around M31. Outnumbering these spirals is a host of dwarf elliptical and irregular galaxies. Examples include SagDEG and the two Magellanic clouds (see pp.310–311), as well as M110 and M32, both ellipticals orbiting the M31

spiral. The Local Group appears to be relatively young. Its major galaxies are all spirals, and there is little matter in the space between galaxies—most of the cluster’s gas is still trapped in the spirals. It is in an early state of cluster evolution. The Milky Way is currently colliding with the Magellanic Clouds, and is heading inexorably toward an ultimate merger with M31.

BARNARD’S GALAXY

This small, irregular galaxy (right), cataloged as NGC 6822, lies 1.7 million light-years away within the Local Group. It is rich in gas and dust, with many pinkish star-birth regions.

FORNAX DWARF GALAXY

BE Y ON D T HE MI LK Y WAY

This dwarf spheroidal galaxy (left) has no obvious nucleus. Such faint and diffuse galaxies are easily missed in more distant galaxy clusters, but they are probably the most numerous.

THE MILKY WAY GALAXY

A major member of the Local Group is the Milky Way galaxy. Earth is within the galaxy’s disk, so our view is edgeon and stretched across the sky.

GALAXY CLUSTERS IRREGULAR CLUSTER

Sculptor Group ALTERNATIVE NAME

South Polar Group 9 million light-years to center

DISTANCE

NUMBER OF GALAXIES

19 (6 major) BRIGHTEST MEMBER

SCULPTOR

NGC 253 (8.2)

Lying just beyond the gravitational boundaries of the Local Group, the Sculptor Group is similar in size to

the Local Group. It is also a young cluster of irregular and spiral galaxies, with no major ellipticals. It is possible that this group, the Local Group, and another group called Maffei 1 were once part of the same larger cluster. The closest member to Earth is NGC 55, an irregular galaxy that, like the Large Magellanic Cloud (see p.310), shows enough structure for some astronomers to consider it a single-armed spiral. The dominant galaxy, however, is NGC 253. This large spiral is the same size as the Milky Way and more than twice the size of any other galaxy in the group.

IRREGULAR CLUSTER

Virgo Cluster ALTERNATIVE NAME

Virgo I Cluster 52 million light-years to center DISTANCE

NUMBER OF GALAXIES

2,000 (160 major) BRIGHTEST MEMBER

VIRGO

M49 (9.3)

The Virgo Cluster is the nearest galaxy cluster worthy of the name; it is a dense collection of galaxies at the heart of the larger supercluster to which the Local Group also belongs. The contrast with smaller galaxy

GALAXY NGC 253

This large spiral dominates the Sculptor Group in this wide-field image. Most of the other galaxies are too faint to be seen without powerful telescopes.

The Virgo Cluster’s core has a high density of large galaxies. The two bright galaxies on the right are the ellipticals M84 and M86.

NGC 253 is a spiral starburst galaxy— a galaxy undergoing a surge of star formation. The surge may have been triggered by a series of supernovae.

X-RAY IMAGING AND CLUSTER GAS Many galaxy clusters are strong sources of X-rays, and orbiting X-ray telescopes can reveal features that remain hidden in visible-light images. While some X-ray sources are located at the centers of the cluster galaxies, the majority of radiation often comes from diffuse gas clouds, independent of the individual galaxies. The process that strips gas out of the cluster galaxies (see p.327) also heats it to generate the X-rays. The distribution of gas offers clues to a cluster’s age and history.

REGULAR CLUSTER

Fornax Cluster CATALOG NUMBER

Abell S 373 65 million light-years to center

DISTANCE

NUMBER OF GALAXIES

54 major galaxies BRIGHTEST MEMBER

FORNAX

NGC 1316 (9.8)

“groups” is striking—the Virgo Cluster contains around 160 major spiral and elliptical galaxies crammed into a volume little larger than that of the Local Group, along with more than 2,000 smaller galaxies. At its heart lie the giant ellipticals M87 (see p.323), M84, and M86, which are thought to have formed from the collisions of spirals over billions of years. Each giant elliptical seems to be at the center of its own subgroup of galaxies— the cluster has not yet settled to become uniform. The cluster’s gravity influences a huge region, extending as far as the Local Group and beyond— the Milky Way and its neighbors are falling toward the Virgo Cluster at 900,000 mph (1.4 million km/h).

CENTER OF THE CLUSTER

STARBURST GALAXY

EXPLORING SPACE

mostly ellipticals, distributed evenly around the giant elliptical NGC 1399. Dwarf galaxies lying between the major ones are also mostly small ellipticals, suggesting that the cluster formed long ago and that interactions between its galaxies have had time to strip away most of their star-forming gas (see p.327). This account of the cluster’s evolution has recently been confirmed by the orbiting Chandra X-ray observatory (see panel, left).

Seyfert’s Sextet CATALOG NUMBERS

NGC 6027 and NGC 6027A–C DISTANCE

190 million light-years NUMBER OF GALAXIES

This image of the Fornax cluster shows X-rayemitting gas in blue. Both central galaxies have trailing plumes of gas, suggesting that the entire cluster is moving through sparser clouds.

4

BRIGHTEST MEMBER

SERPENS

NGC 6027 (14.7)

Seyfert’s Sextet actually contains just four members—each a misshapen spiral galaxy locked to the others in a gravitational waltz within a region of space no larger than the Milky Way. The sextet, as seen from Earth, is completed by a small face-on spiral that happens to lie in the background, and by a distorted star cloud (at lower right in the image below).

In the Fornax Cluster’s central region lie NGC 1399 (upper left of center) and NGC 1365 (bottom right). As a rule, elliptical galaxies predominate.

QUARTET PLUS TWO

B EY O N D TH E MI L KY WAY

Fornax is home to a relatively nearby galaxy cluster, centered at around the same distance as the Virgo Cluster. However, the Fornax Cluster is at a later stage of evolution than the younger GALAXY NGC 1365 Virgo group. Here, One of the Fornax spiral galaxies are Cluster’s few spirals, rare—the cluster’s NGC 1365 has a dust bar through its core. major galaxies are

COMPACT GROUP

CLUSTER CORE FORNAX IN X-RAYS

329

THE VIRGO CLUSTER

Over 2,000 galaxies reside in the Virgo Cluster (see p.329), the nearest large cluster to us, some 50 million light-years away. The brightest of them are visible through amateur telescopes. Just below center is the elliptical galaxy M87 (see p.320), also known as the radio source Virgo A. M87 has an estimated mass of 2.4 trillion Suns, making it the biggest galaxy in our region of the Universe.

332

GALAXY CLUSTERS REGULAR CLUSTER

COMPACT GROUP

Hydra Cluster CATALOG NUMBER DISTANCE

Stephan’s Quintet

Abell 1060

CATALOG NUMBER

Hickson 92

160 million light-years

DISTANCE

NUMBER OF GALAXIES

340 million light-years (NGC 7320: 41 million light-years)

1,000+ BRIGHTEST MEMBER

NGC 3311 (11.6)

HYDRA

The Hydra Cluster is similar in size to the huge Virgo Cluster (see p.329). It is the closest example of a “relaxed” cluster (see p.327) of mainly elliptical galaxies in a spherical distribution. Its hot X-ray gas also forms a spherical cloud around the core. The cluster is centered on two giant elliptical galaxies and an edge-on spiral, each 150,000 light-years across. These galaxies are interacting—the ellipticals’ gravity has warped the spiral, while both ellipticals have distorted outer haloes. The cluster is the major member of the Hydra Supercluster, which adjoins the Local Supercluster (see pp.336–39). HEART OF THE HYDRA CLUSTER

In this image, the central giant ellipticals NGC 3309 and 3311 lie below the large, blue spiral NGC 3312. The two bright objects on either side are foreground stars.

NUMBER OF GALAXIES

PEGASUS

4/5

BRIGHTEST MEMBER

NGC 7320 (13.6)

First observed by French astronomer E. M. Stephan at the University of Marseilles in 1877, Stephan’s Quintet appears to be a remarkably compact cluster of five galaxies. The galaxies are a mixture of spirals, barred spirals, and ellipticals and show clear signs of disruption from interactions. The largest galaxy as seen from Earth, NGC 7320, is probably a foreground object lying in front of a quartet of interacting galaxies. The spectral red shift (see p.35) of NGC 7320 is much smaller than those of the other four galaxies, and instead matches that of several other galaxies close to it in the sky. Since it also appears physically different from the quartet, it seems likely that NGC 7320 is much closer and the unusual red shift is a normal result of the expansion of space (see p.44). However, a few astronomers claim that trails of material link NGC 7320 to other Quintet galaxies. If this is the case, then the red shift suggests that the galaxy is moving very fast relative to its neighbors and toward Earth, therefore reducing its overall speed of recession and its red shift. Or perhaps the red shift does not originate from its motion at all. These competing theories have turned Stephan’s Quintet into a battleground for the small minority of astronomers who think that red shifts are not all caused by the expansion of space, and that Hubble’s Law (see p.44) does not always apply.

SPIRAL SILHOUETTE

BE Y ON D T HE M I L KY WAY

NGC 3314, an unusual case of one spiral galaxy silhouetted against another, is one of Hydra’s most beautiful objects.

REGULAR CLUSTER

Coma Cluster CATALOG NUMBER

Abell 1656 DISTANCE

300 million light-years NUMBER OF GALAXIES

3,000+ BRIGHTEST MEMBER

COMA BERENICES

NGC 4889 (13.2)

Although it lies near the Virgo Cluster in the sky (see p.329), the Coma Cluster is much farther away. First recognized by William Herschel as a concentration of “fine nebulae”

FOUR OR FIVE?

QUINTET CLOSE-UP

The quintet consists of a quartet of yellow galaxies beside the white spiral NGC 7320. The contrasting appearance of NGC 7320 suggests it lies in front of the other galaxies.

This detailed Hubble Space Telescope view of Stephan’s Quintet shows chains of stars linking several of its interacting galaxies.

in 1785, this is one of the nearest highly evolved or “relaxed” galaxy clusters (see p.327). It is very dense, with over 3,000 galaxies, and is dominated by elliptical and lenticular galaxies. Because it is near the north galactic pole (and therefore free of the dense star fields of the Milky Way), it is well studied. Swiss-American astronomer Fritz Zwicky used Coma when he made the first measurements of galaxy movements within a cluster in the 1930s. He found the cluster contained many times more mass than its visible galaxies suggested—an idea that was not accepted until the 1970s. Overall, the cluster is moving away at 16 million mph (25 million km/h). At

the cluster’s center lie the giant elliptical NGC 4889 and the lenticular galaxy NGC 4874. Most of the spirals and irregulars are in the outer regions. X-ray images show two distinct patches of cluster gas, suggesting that the cluster is absorbing a smaller cluster of galaxies. Like the Virgo and Hydra clusters, Coma forms the core of its own galaxy supercluster. COMA ELLIPTICAL

This image is dominated by the Coma Cluster elliptical NGC 4881 and a nearby spiral. The other galaxies are far more distant.

GALAXY CLUSTERS IRREGULAR CLUSTER

Hercules Cluster CATALOG NUMBER

Abell 2151 DISTANCE

500 million light-years NUMBER OF GALAXIES

100+ BRIGHTEST MEMBER

HERCULES

NGC 6041A (14.4)

The small Hercules Cluster is dominated by spiral and irregular galaxies, suggesting that it is in an early

stage of development. In keeping with the best models of such clusters’ formation (see p.327), it shows little sign of structure. Within the cluster, several pairs or groups of galaxies seem to be merging or interacting— encounters that will transform them into different kinds of galaxies and reduce their random movements until they become more evenly distributed. The most prominent of these mergers is NGC 6050, a pair of interlocking spiral galaxies near the cluster’s center that may eventually form the core of a giant elliptical, such as those found in more evolved clusters.

333

REGULAR CLUSTER

GEORGE ABELL

Abell 1689 CATALOG NUMBER

Abell 1689 DISTANCE

2.2 billion light-years NUMBER OF GALAXIES

3,000+ BRIGHTEST MEMBER

VIRGO

Unnamed galaxy (17.0)

Abell 1689 is one of the densest galaxy clusters known, with thousands of galaxies packed into a volume of space only 2 million light-years across. Its ball shape makes it a fine gravitational lens, bending the images of distant galaxies into arcs. By noting the lensing power throughout the cluster, astronomers have worked out the distribution of the cluster’s dark matter.

George Abell (1927–1983) was a career astronomer and popularizer of science who carried out the first, and most influential, survey of galaxy clusters. After working on the Palomar Sky Survey during the 1940s and 1950s, using the Palomar Schmidt telescope, he turned his attention to analyzing the results, developing methods for distinguishing galaxy clusters from isolated field galaxies, and classifying clusters into types.

HERCULES FIELD

This wide-field view captures most of the bright galaxies in Hercules and shows their irregular, “unrelaxed” distribution. LENSING IN CLUSTER ABELL 1689

REGULAR CLUSTER

IRREGULAR CLUSTER

Abell 2065

Abell 2125 CATALOG NUMBER

CATALOG NUMBER

Abell 2065

Abell 2125

DISTANCE

DISTANCE

1 billion light-years

3 billion light-years

NUMBER OF GALAXIES

NUMBER OF GALAXIES

1,000+

1,000+

BRIGHTEST MEMBER

CORONA BOREALIS

PGC 54876 (16.0)

Magnitude 17.0

Abell 2125 has been the subject of intense scrutiny from the orbiting Chandra X-Ray Observatory. The cluster lies close enough to Earth to see detail, but so far away that images reaching Earth show an early and still active phase of its evolution, 3 billion years ago. Abell 2125 is therefore ideal for testing ideas on cluster formation.

ZOOMING IN ON C153

THE CORONA BOREALIS CLUSTER

This sequence of Chandra X-ray images zooms into the hot gas cloud at the core of Abell 2125, showing how gas is being stripped from galaxy C153 (right).

them through the intergalactic medium. A fainter cloud of almost equal size, enveloping hundreds more galaxies, has remarkably few heavy elements, suggesting that the gasstripping process becomes more powerful and thorough over time, and that the cloud is much younger than its fainter neighbor. Since X-ray evidence shows so much activity within the cluster, astronomers have also imaged it at other wavelengths. Infrared telescopes, for example, have revealed enormous bursts of star formation going on in galaxies far from the cluster center. One possible explanation is that, even at distances of up to 1 million light-years, the tidal forces from the center of a large cluster are enough to disrupt nearby galaxies and trigger starbursts.

BE Y ON D TH E M I LK Y WAY

Abell 2065, also known as the Corona Borealis Cluster, contains 400 or more large galaxies. A highly evolved cluster like the Coma Cluster (opposite), it emits X-rays from a diffuse cloud of hot gas. However, X-ray observations have found two distinct X-ray cores, suggesting that Abell 2065 may be two already ancient clusters merging together. The cluster lies at the center of the Corona Borealis Supercluster.

BRIGHTEST MEMBER

URSA MINOR

X-ray images reveal what optical ones cannot—that the cluster is forming from the merger of several smaller clusters. The most intense cloud of X-ray emitting gas shows “clumpiness,” which indicates it has recently come together. Spectra reveal that the cloud is enriched with heavy elements such as iron, and close-up images show gas actively being stripped away from galaxies such as C153. With it, the gas carries atoms of heavy metals created in supernova explosions, distributing

BE Y ON D T HE MI LK Y WAY

334

REGULAR CLUSTER

Abell 2218 CATALOG NUMBER

Abell 2218 DISTANCE

2 billion light-years NUMBER OF GALAXIES

250 or more BRIGHTEST MEMBER

DRACO

Unnamed galaxy (17.0)

Abell 2218 is a spectacular example of a highly evolved and extremely dense galaxy cluster. It contains more than 250 mostly elliptical galaxies in a volume of space roughly 1 million light-years across.

The cluster has taught astronomers much about galaxy clusters, and about galaxies themselves. The cluster’s density is so great that it affects the shape of the surrounding space, as predicted by Einstein’s theory of general relativity (see p.42). Many more distant galaxies lie directly behind the cluster, and as light rays from these objects pass close to Abell 2218, their paths are deflected and focused toward Earth, in the same way that a magnifying lens focuses sunlight. This gravitational lensing (see p.327) brightens the images of galaxies that would otherwise be too far away to detect. It results in a series of distorted images of distant galaxies ringing the center of Abell 2218.

The galaxies beyond Abell 2218 lie much farther away, and therefore their images come from a much earlier time. Most of the lensed galaxies are blue-white, suggesting they are young irregulars and spirals very different from Abell 2218’s own aged ellipticals. Some of the lensed galaxies align with X-ray sources, suggesting they are active galaxies. Recent studies yielded images of a galaxy so far beyond Abell 2218 that all its light has been redHOLE IN THE COSMIC BACKGROUND

In this composite image of Abell 2218, yellow and red depict the X-ray-emitting gas around its core. The gas scatters the cosmic microwave background radiation, creating a hole, outlined here by contours.

335 DISTORTED BY GRAVITY

Most of the bright objects in this image are galaxies in the Abell 2218 cluster. The arcs are much more remote galaxies, their images distorted by Abell 2218’s gravity.

EXPLORING SPACE

MAPPING THE MISSING MASS Astronomers have now begun to use Abell 2218 to probe the origins of the universe. A phenomenon called the Sunyaev–Zel’dovich effect (see caption, opposite) creates holes and ripples in the cosmic microwave background radiation shining through the cluster. This happens because gas around Abell 2218’s core scatters photons of microwave radiation, just as Earth’s atmosphere scatters light. The strength of these ripples can be used to estimate the true diameter of the cluster’s core, and therefore its distance from Earth, independently of its red shift. The red shift and distance can then be used together to find the expansion rate of the universe (see p.44).

spikes coincide with galaxies

The total mass of a cluster can be up to five times that of its visible galaxies, but the distribution of the other, dark matter was a mystery until recently. Gravitational lensing now allows astronomers to measure the missing mass in clusters. By analyzing images of lensed galaxies, astronomers can pinpoint concentrations of mass distorting the light as it passes through the cluster. cluster gas and dark matter appear as a broad hump around the cluster’s core

MAP OF CLUSTER CL0024+1654

This mass map shows the difference in distributions of visible and dark matter in a mature galaxy cluster.

B EY O N D TH E MI L KY WAY

shifted into the infrared part of the spectrum. At the time, it was the most distant galaxy known, at 13 billion light-years from Earth. It must have formed shortly after the first stars, in the aftermath of the Big Bang. Gravitational lensing can also reveal hidden properties of Abell 2218 itself. Because the strength of lensing depends on the cluster’s density, it offers a measure of the distribution of all matter in the cluster—including the dark matter. Abell 2218 is one of the few galaxy clusters in which the pattern of visible matter (galaxies and X-ray-emitting gas) and the calculated distribution of dark matter do not match, suggesting the cluster is not as uniform as it appears in visible light.

336

GALAXY SUPERCLUSTERS

GALAXY SUPERCLUSTERS 22–23 The scale of the universe 24–27 Celestial objects 28–31 Matter 34–37 Radiation 326–27 Galaxy clusters

THE LARGEST-SCALE STRUCTURES

in the universe are galaxy superclusters—collections of neighboring galaxy clusters that bunch together in chains and sheets stretching across the cosmos. These structures are echoes of those that formed in the Big Bang, and by studying the universe at these enormous scales astronomers can learn about the way it formed and our place within it.

GALAXY SUPERCLUSTERS Just as galaxies are bound together by gravity into clusters, galaxy clusters themselves blur together at their edges to form even larger structures called superclusters. While individual clusters are typically about 10 million light-years in diameter (see p.326), superclusters are typically up to 200 million light-years across and merge with others at their edges. Where superclusters overlap, it is the gravitational behavior of individual clusters that determines to which supercluster they belong. The enormous size of superclusters and the great mass of galaxies in them allows them to modify the cosmological expansion of space (see pp.44–45), resulting in largescale variations in the movement of galaxies. The best known example of this is a generalized flow of galaxies in our part of the universe, possibly toward a region known as the Great Attractor but more probably toward the more massive Shapley Supercluster directly behind it. Sculptor Group Local Group

Fornax Cluster

Virgo Cluster

Maffei group

Virgo III groups

circle is 200 million light-years across

PLOT OF GALAXIES

This plot of a section of sky out to a distance of 1 billion light-years shows how galaxies cluster on the largest scale.

Leo II groups

MAP OF THE LOCAL SUPERCLUSTER

BE Y ON D TH E M I LK Y WAY

This map of the Virgo Supercluster, centered on the Local Group, shows groups and clusters of galaxies linked into a chain. Each point denotes a major galaxy—there are thousands of smaller ones not pictured. UKIDSS SURVEY

The core of the Virgo Cluster is seen here at infrared wavelengths. Infrared surveys give a more accurate measure of the number of stars in a galaxy than visible-light surveys. They also reveal very distant galaxies whose light has been shifted into the infrared by cosmological expansion. The UKIRT Infrared Deep Sky Survey (UKIDSS) has mapped hundreds of millions of galaxies since 2005.

THE GREAT ATTRACTOR

This view of the sky shows galaxies in the direction of the Great Attractor. Recent studies suggest that galaxies are moving toward the Shapley Supercluster behind the Attractor, rather than the Attractor itself.

THE LOCAL SUPERCLUSTER A chain of galaxy clusters links our own small Local Group of galaxies, containing the Milky Way, to the Virgo Cluster, some 52 million lightyears from Earth. This much larger cluster, containing up to 2,000 galaxies, marks the gravitational heart of the Local Supercluster (also known as the Virgo Supercluster). The Local Supercluster contains at least 100 separate bright galaxy clusters scattered across 110 million light-years of space. About two-thirds of these galaxy clusters are concentrated in a flattened, disklike plane, while the remainder are scattered throughout a spherical halo. However, in comparison with some other superclusters, the Local Supercluster appears to be relatively small and lightweight, with just a single large cluster—the Virgo Cluster—at its heart surrounded by many smaller ones. Nevertheless, the Virgo Cluster’s gravity is counteracting cosmic expansion, pulling other clusters—including our own—toward it at speeds of up to 3.4 million mph (5.4 million kph).

GALAXY SUPERCLUSTERS

337

LARGE-SCALE STRUCTURE

A computer simulation of the large-scale structure of the universe shows the concentration of matter into filaments across a billion light-years of space. According to models of cosmic evolution, dark matter (yellow) formed clumps around which visible matter (lighter pinks) coalesced. Clusters of galaxies are concentrated at nodes where filaments meet; superclusters are strung out along the filaments.

THE ORIGIN OF SUPERCLUSTERS The sheer size of galaxy superclusters makes their origins important in understanding the structure and properties of the universe as a whole. Theoretically, superclusters could either have formed from the gradual coalescence of matter pulled together by gravity alone, or they could mark largescale concentrations of matter that were present from the earliest times and within which galaxies and galaxy clusters subsequently developed. The first detailed maps of the cosmic microwave background radiation (CMBR), produced by the COBE satellite in 1992, provided evidence that large-scale structures were present from the earliest times, confirming the second theory. The structures themselves are thought to have originated as microscopic variations in temperature and density in the early universe and then enlarged to enormous scale by cosmic expansion, eventually giving rise to the “Swiss cheese” distribution of matter in the universe today. RADIATION FROM THE SKY

This elliptical map shows tiny variations in the temperature of the cosmic microwave background radiation (CMBR) over the whole sky, as measured by the Wilkinson Microwave Anisotropy Probe (WMAP). The variations—anisotropies—are color-coded according to the temperature scale shown below. TEMPERATURE VARIATION IN THE CMBR

-0.0002°C

-0.0001°C

0°C

+0.0001°C

+0.0002°C

the red band running across the center of the map is caused by microwaves from the Milky Way

radiation detected by WMAP satellite

THE GREAT COLD SPOT Hubble Space Telescope

Big Bang

Wilkinson Microwave Anisotropy Probe (WMAP)

afterglow radiation

377,000 YEARS AFTER BIG BANG

300 MILLION YEARS AFTER BIG BANG DARK AGES

1 BILLION YEARS AFTER BIG BANG PRESENT: 13.7 BILLION YEARS AFTER BIG BANG

This large cold spot in the CMBR may be due to a huge void around 6–10 billion light-years away.

SEEING THE FIRST LIGHT

The cosmic background microwave radiation detected by WMAP consists of photons that “escaped” from matter less than 380,000 years after the Big Bang. This was after the first atoms formed but before the first stars ignited—a period known as the Dark Ages. In contrast, Hubble can observe back only to about 400–800 million years after the Big Bang, when early galaxies had formed.

B EY O N D TH E MI L KY WAY

first stars ignite

light from early galaxies observed by Hubble Space Telescope

338

GALAXYS

FILAMENTS AND VOIDS At the largest scales measured, the universe reveals a clear overall structure. Galaxy superclusters join to form string-like “filaments” or flat “sheets” around the edges of enormous and apparently empty regions known as “voids.” While galaxy structure up to the level of clusters can be explained by the action of gravity since the Big Bang, the present age of the universe (13.7 billion years) is not nearly long enough for gravity alone to have organized the universe on the scale of filaments and voids. This indicates that large-scale cosmic structures are, in fact, expanded “echoes” of features from the earliest times. The first filaments to be discovered were galactic “walls” identified in the 1980s, and since then it has become clear that filaments contain not only luminous galaxies but also enormous clouds of hydrogen known as Lyman Alpha blobs. The first void, meanwhile, was discovered during a galaxy survey in 1978. Typically, voids are empty of both normal and dark matter, although some voids have been found to contain a few galaxies.

5 BILLION LIGHT-YEARS ACROSS

150 MILLION LIGHT-YEARS ACROSS

4 MILLION LIGHT-YEARS ACROSS

GALAXY MAP FROM THE SLOAN SURVEY

Begun in 2000, the Sloan Digital Sky Survey is a major red-shift survey that has so far mapped more than a million objects, out to 2 billion light-years from Earth. On this map, each dot represents a galaxy, and the galaxies are plotted at distances from the centre proportional to their distance from Earth.

each dot is a separate galaxy, color-coded according to the average age of its stars: red dots contain older stars; blue and green are younger stars

THE COSMOLOGICAL PRINCIPLE

This principle is the assumption that at the largest scales the universe is essentially uniform in all its properties and in all directions, even though it is clearly not so at smaller scales. The principle seems to be borne out in practice—for example, when comparing the distribution of galaxies, as shown above.

unmapped sections are areas blocked from the telescope’s view by the Milky Way

BETWEEN THE SUPERCLUSTERS

QUASAR

INTERGALACTIC CLOUD

peak radiation from quasar

intensity

B EY O N D TH E M I LK Y WAY

Studying luminous galaxies alone can give a deceptive view of the universe—not all normal matter produces detectable radiation, and dark matter neither produces radiation nor interacts with it. However, by analysing light from distant quasars (see p.320), astronomers can measure the effects of intervening, but otherwise invisible, hydrogen clouds. As light from the quasars passes through such clouds, the hydrogen “imprints” it with absorption lines that form a pattern called a Lyman Alpha forest. The wavelengths of these absorption lines reveal the red shifts of the clouds and therefore their distance from Earth, allowing their distribution to be mapped. In addition, analysing localized movements among galaxy clusters allows astronomers to map the distribution of dark matter. Both of these methods seem to confirm that the voids between superclusters are empty and that most normal and dark matter is concentrated around the visible galaxy filaments. photons

the edge of the survey map is about 2 billion light-years away from the Milky Way

dark regions in the mapped area are huge voids in space

filamentary structures are strings of galaxy clusters that are only partially mapped

INTERGALACTIC CLOUD

EARTH

red-shifted peak red-shifted line

wavelength absorption by cloud introduces line

absorption by cloud introduces another line

LYMAN-ALPHA FOREST

Light from a distant quasar passes through a series of hydrogen clouds on its way to Earth. Each superimposes a Lyman Alpha absorption line onto the quasar’s spectrum, but red shifts mean the lines do not overlap. The result is a series of red-shifted lines called a Lyman Alpha forest. red-shifted lines building up into a forest

GALAXY SUPERCLUSTERS

MAPPING DEEP SPACE REGION DETAILED BY GALAXY MAP

area depicted in survey galaxy map

The galaxy map below covers two thin, wedge-shaped regions of space, still only representing a small fraction of the observable universe.

Earth

edge of observable Universe

part of the Shapley Concentration, or Shapley Supercluster; this is a huge group of about 25 clusters of galaxies

While galaxy motions on a local scale are affected by gravitational influences such as the presence of superclusters, on the scale of the universe as a whole these effects should become negligible in comparison to the overall cosmic expansion resulting from the Big Bang (see pp.48–51). According to Hubble’s Law, the speed at which a far-off galaxy is moving away from us is, on average, proportional to its distance, and as a result the red shift in a distant galaxy’s light can be used as a measure of its distance. The first large-scale survey of galaxy red shifts, carried out by the Harvard-Smithsonian Center for Astrophysics (CfA), started in 1977 and took five years to measure 13,000 galaxies. Since then other surveys, such as the Sloan Digital Sky Survey and Two-degree-Field Galaxy Redshift Survey (2dFGRS), have mapped many more galaxies. These surveys have confirmed that the large-scale pattern of galaxy distribution remains essentially identical out to distances of billions of light-years.

0.14

0.12

0.10

0.08

0.06

values on the red-shift scale are a measure of how fast galaxies are receding from Earth; they are also an indication of distance from Earth

Major galaxy red-shift surveys typically use multi-object spectrographs—devices that can simultaneously record the spectra of hundreds of objects. Instruments such as the Gemini multi-object spectrographs, mounted on two large telescopes in Hawaii and Chile, use special masks to separate light from the different objects before splitting it through a diffraction grating to obtain the spectra.

GALAXY DISTRIBUTION PLOT FROM THE 2DFGRS

Centered on Earth, this plot shows the positions of over 230,000 galaxies. The dots are galaxies and the colors indicate density, with dense regions redder and less dense ones bluer.

IF EXPANSION HAS OCCURRED AT A STEADY RATE observer’s view of a supernova

APPARENT BRIGHTNESS

Earth

type 1a supernova

1

distances and apparent brightness change steadily with increase in red shift

EVIDENCE FOR ACCELERATING EXPANSION

1/3

1/6

IF EXPANSION HAS ACCELERATED observer’s view of a supernova Earth

The brightness of type 1a supernovae indicates their distance from Earth, while their red shifts indicate how fast they are receding. If the universe is expanding at a steady rate, the brightness of a supernova should be proportional to its red shift (top). However, studies have found that distant supernovae are fainter than their red shifts suggest (bottom), indicating that expansion of the universe is accelerating.

type 1a supernova

1

1/6

1/25

distance rises at an increasing rate with increase in red shift; highest red-shift supernovae are more distant and so fainter

BE YO N D TH E M I LKY WAY

One of the most remarkable recent astronomical discoveries has been the fact that cosmic expansion is accelerating. Studies of type 1a supernovae (see p.283) have revealed that they are unexpectedly faint in the most distant galaxies, which implies that they are further away than they should be if the rate of expansion of the universe was constant or slowing down. Many cosmologists had expected the expansion of the universe to slow down as the initial impetus from the Big Bang began to fade, so the discovery that its expansion is getting faster implied that an important factor was missing from cosmological theories. Furthermore, the acceleration seems to have begun only around 5 billion years ago, with the universe slowing as predicted until then. Since its discovery in 1998, the accelerating expansion has been corroborated from other measurements, and it is now generally believed to be due to dark energy (see p.58). According to recent measurements, dark energy may be the most abundant form of mass-energy in the universe, accounting for almost 73 percent of the total.

OBSERVING A MILLION GALAXIES

The Gemini observatory has two 26.9 ft (8.1 m) reflectors—one in Chile (shown above), the other in Hawaii—each fitted with a spectrograph for multi-object spectroscopy.

Earth and the Milky Way are at the central point of the map

ACCELERATING EXPANSION

EXPLORING SPACE

GEMINI OBSERVATORY

APPARENT BRIGHTNESS

0.04

0.02

The Sloan Great Wall, a giant filament, is the largest known structure in the universe, at 1 billion light-years across

339

TWO-MICRON ALL-SKY SURVEY (2MASS)

This panoramic view of the entire sky at nearinfrared wavelengths illustrates the distribution of galaxies beyond the Milky Way. The plane of the Milky Way runs across the center of this projection. Galaxies are color-coded by their red shift, from blue (the nearest) via green (intermediate distances) to red (the farthest). The purple area at top center right is the Virgo Cluster of galaxies.

THE NIGHT SKY

TH E N I G H T S KY

344

“Why did not somebody teach me the constellations, and make me at home in the starry heavens, which are always overhead, and which I don’t half know to this day?” Thomas Carlyle

THE HUMAN EYE HAS ALWAYS seen patterns among the stars. Ancient peoples traced the figures of gods, heroes, and mythical animals onto the skies and used the relationship between these constellations to illustrate myths and legends. In most cases, stars within a constellation lie in the same region of sky merely by chance, however, and are not related. Despite the apparent permanence of the skies, these patterns are not fixed, because all the stars are moving relative to Earth. Over time, the shape of all the constellations will change, and hundreds of thousands of years from now, they will be unrecognizable. Future generations will need to invent constellations of their own. But for now, 88 constellations fill our sky, interlocking like pieces of an immense jigsaw puzzle. Some are large, others small, some richly stocked with objects of note, others faint and seemingly barren. All are featured in the following pages. PATTERNS IN THE SKY

As darkness falls, a stargazer scans the sky with binoculars. The familiar shape of the Big Dipper looms overhead, part of the constellation Ursa Major, the Great Bear. The north pole star, Polaris, can be seen high up on the right.

THE CONSTELLATIONS

346

THE CONSTELLATIONS

THE HISTORY OF CONSTELLATIONS 62–63 The celestial sphere 64–65 Celestial cycles 70–71 Star motion and patterns 76–77 Naked-eye astronomy

THE FIRST CONSTELLATIONS

were patterns of stars that ancient peoples employed for navigation, timekeeping, and storytelling. Recently, the pictorial aspect of constellations has become less significant, and they have become simply delineated regions of the sky, although the attraction of the myths and legends remains.

EARLY CONSTELLATION LORE The constellation system used today stems from patterns recognized by ancient Greek and Roman civilization. The earliest surviving account of ancient Greek constellations comes from the poet Aratus of Soli (c. 315–c. 245 bc). His poem, the Phaenomena, written around 275 bc, describes the sky in storybook fashion and identifies 47 constellations. It is based on a lost book of the same name by the Greek astronomer Eudoxus (c. 390–c. 340 bc). Eudoxus reputedly introduced the constellations to the Greeks after learning them from priests in Egypt. These constellations had been adopted from Babylonian culture; they were originally created by the Sumerians around 2,000 bc. However, the Greeks attached their own myths to the constellations detailed by Eudoxus, and Aratus’s storybook of the stars proved immensely popular. Sometime in the 2nd century ad, it was joined by a more elaborate work of constellation lore called Poetic Astronomy, written by the Roman author Hyginus. Many editions of both these works were produced and translated over the centuries.

ANTICANIS

This page from a 9th-century edition of the star myths of Hyginus shows the constellation Canis Minor, here termed Anticanis. Hyginus’s words, in Latin, form the shape of the dog’s body.

T HE N I G H T S K Y

FILLING THE HEAVENLY SPHERE The oldest surviving star catalog dates from the 2nd century ad and is contained in a book called the Almagest, written by the Greek astronomer and geographer Ptolemy (see panel, opposite). It records the positions and brightnesses of one thousand stars, arranged into 48 constellations, based on an earlier catalog by Hipparchus of Nicaea (c. 190–c. 120 bc). In the 10th century ad, an Arab astronomer, al-Sufi (see p.421), updated the Almagest in his Book of Fixed Stars, which included Arabic names for many stars. These Arabic names are still used today, although often in corrupted form. No more constellations were introduced until the end of the 16th century, when Dutch explorers sailed to the East Indies. From there, they could observe the southern sky that was below the European horizon. Two navigators, Pieter Dirkszoon Keyser and Frederick de Houtman (see p.416), cataloged nearly 200 new southern stars, from which they and their mentor, Petrus Plancius (see p.358), a leading Dutch cartographer, created 12 new constellations. Plancius also created other northern constellations, forming them between those listed by Ptolemy. Nearly a century later, Johannes Hevelius (see p.384), a Polish astronomer, filled the remaining gaps in the northern sky, and in POCKET GLOBE the mid-18th century, the French This pocket globe from the National Maritime astronomer Nicolas Louis de Museum, England, positions the Earth within a Lacaille (see p.422) introduced shell that represents the surrounding celestial another 14 constellations in sphere. On the inside of the open shell are the the southern sky. constellations, painted as mirror images.

GLOBAL COVERAGE

This beautiful celestial globe was made around 1625 by Arnold van Langren, a celebrated Dutch globe-maker. As with all celestial globes, the figures are shown reversed in comparison to their appearance in the sky.

THE HISTORY OF CONSTELLATIONS

347

STAR CHARTS AND ATLASES The first printed star chart was produced in 1515 by the great German artist Albrecht Dürer. Like a celestial globe, Dürer’s chart depicted the constellations in reverse, showing the sky as it would be seen from an imaginary position outside the celestial sphere, but before long, charts were being made that could be compared directly with the sky. The finest early star atlas was Uranometria, produced in 1603 by the German astronomer Johann Bayer. This atlas remains SKETCHY FIGURES Leo, the Lion, an easily recognizable one of the most beautiful constellation of the zodiac, is here depicted examples of the celestial on the Atlas Coelestis, by English astronomer cartographer’s art. Shortly John Flamsteed, published in 1729. after its publication, astronomy was revolutionized by the invention of the telescope. The first major star catalog and atlas of this new era was produced by England’s first Astronomer Royal, John Flamsteed (1646-1719). Atlas Coelestis shows the Ptolemaic constellations visible from Greenwich, England, based on Flamsteed’s own painstaking observations. The pinnacle of celestial mapping came in 1801, when Johann Bode, a German astronomer, published an atlas called Uranographia. Covering the entire sky, this atlas depicted over 100 constellations, some invented by Bode himself. Finally, in 1922, a list of 88 constellations was agreed upon by the International Astronomical Union, astronomy’s governing body, which also defined the boundaries of each constellation. On modern star charts, the only sign of the traditional pictorial charts are the few lines that link the main stars, suggesting the overall shape of each constellation.

PTOLEMY Ptolemy (c. ad 100–170) lived and worked in the great metropolis of Alexandria, Egypt, which was then part of the Greek empire. He was one of the last—and the greatest— of the ancient Greek astronomers. His Earth-centered model of the universe, outlined in the treatise Almagest, dominated astronomical theory for 1,400 years. Ptolemy also made a catalogue of 1,022 stars in 48 constellations, based on earlier work by Hipparchus.

Ancient people imagined gods, heroes, and beasts among the stars, and these figures were depicted on star charts until the 19th century. These charts, from John Flamsteed’s Atlas Coelestis (1729), show those 48 constellations known to the ancient Greeks depicted on the northern and southern halves of the sky.

TH E NI G H T S KY

HEAVENLY PICTURE BOOK

348

THE CONSTELLATIONS VELA

MAPPING THE SKY

-50 celestial coordinates

CENTAURUS

deep-sky object

-60

˚

Hadar

linking lines join constellation figure

MUSCA

CONSTELLATION CHARTS

60°N 40°N

Partially visible

-70

˚

Each of the 88 constellation entries has its own chart, centered around the constellation area. These charts show all stars brighter than magnitude 6.5. Within the constellation borders, every star brighter than magnitude 5 is labeled. Deep-sky objects are represented by an icon.

80°N Not visible

20°N

μ γ CRUX δ λβ ε NGC ι 4755 Coal- α θ1,2 sack Acrux ζ CARINA η

constellation border

The following pages divide the celestial sphere into six parts— two polar regions and four equatorial regions—which show the location of the 88 constellations. Each constellation is then profiled in the following section. Each entry places the constellation and its main features into the context of the rest of the sky. VISIBILITY MAPS

˚

Galaxy Globular cluster

KEY TO STAR MAGNITUDES

20°S

Open cluster

40°S 60°S

-1.5–0

The entry for each constellation contains a map showing the parts of the world from which it can be seen. The entire constellation can be seen from the area shaded black, part is visible from the area shaded gray, and it cannot be seen from the area shaded white. Exact latitudes for full visibility are given in the accompanying data set.

THE NORTH POLAR SKY

11h

DEEP-SKY OBJECTS

0° Visible

12h

13h

14h

0–0.9

1.0–1.9

2.0–2.9

3.0–3.9

4.0–4.9

5.0–5.9

Diffuse nebula

6.0–6.9

Planetary nebula or supernova remnant

18h 17h

19h Black hole or X-ray binary

CYGNUS

21h

DRACO BOOTES 22h

CEPHEUS LACERTA 23h

URSA MINOR

90

TH E N I G H T S KY

URSA MAJOR

Almost in the center of this chart is the star Polaris, in Ursa Minor, which lies less than 1° from the north celestial pole. For observers in the Northern Hemisphere, the stars around the pole never set—they are circumpolar. The viewer’s latitude will determine how much of the sky is circumpolar: the farther north, the larger the circumpolar area. This chart shows the sky from declinations 90° to 50°.

80

˚

˚

70

60

˚

PERSEUS

CAMELOPARDALIS 3h

4h 1

2

3

4

˚

1h

LYNX

0

50

CASSIOPEIA

STAR MAGNITUDES -1

˚

5

Variable star

AURIGA

Star magnitudes shown here are for the equatorial and polar sky charts

5h

7h 6h

2h

0h

MAPPING THE SKY THE GREEK ALPHABET

On most star charts, bright stars are identified by Greek letters according to a system invented by Johann Bayer (see p.72).

349

VISIBILITY ICONS

Alpha Beta Gamma Delta Epsilon Zeta

α β γ δ ε ζ

Eta Theta Iota Kappa Lambda Mu

η θ ι κ λ μ

Nu Xi Omicron Pi Rho Sigma

ν ξ ο π ρ σ

Tau Upsilon Phi Chi Psi Omega

τ υ φ χ ψ ω

Beside every photograph is an icon indicating the kind of view it illustrates. Some photographs show the star or deep-sky object as it can be seen by the naked eye, through binoculars, or through amateur telescopes. Others are the result of CCD photography or show the view through professional observing equipment.

2 1 5 4 3

Naked eye Binoculars Telescope (amateur) CCD Professional equipment

ALPHABETICAL INDEX OF THE 88 CONSTELLATIONS

The constellation entries are ordered by their position on the celestial sphere, beginning with Ursa Minor in the north and spiraling south in a clockwise direction, before finishing with Octans. This alphabetical list provides an alternative way of locating constellation entries. Andromeda Antlia Apus Aquarius Aquila Ara Aries Auriga Boötes Caelum Camelopardalis Cancer Canes Venatici

p.368 p.396 p.423 p.387 p.383 p.415 p.371 p.359 p.363 p.405 p.358 p.375 p.362

Canis Major Canis Minor Capricornus Carina Cassiopeia Centaurus Cepheus Cetus Chamaeleon Circinus Columba Coma Berenices Corona Australis

p.392 p.392 p.404 p.411 p.357 p.398 p.356 p.389 p.423 p.413 p.408 p.376 p.415

Corona Borealis Corvus Crater Crux Cygnus Delphinus Dorado Draco Equuleus Eridanus Fornax Gemini Grus Hercules Horologium

p.379 p.397 p.397 p.412 p.366 p.385 p.421 p.415 p.385 p.406 p.405 p.374 p.417 p.364 p.419

Hydra Hydrus Indus Lacerta Leo Leo Minor Lepus Libra Lupus Lynx Lyra Mensa Microscopium Monoceros Musca

p.394 p.419 p.416 p.369 p.377 p.376 p.407 p.379 p.399 p.359 p.365 p.422 p.403 p.393 p.413

Norma Octans Ophiuchus Orion Pavo Pegasus Perseus Phoenix Pictor Pisces Piscis Austrinus Puppis Pyxis Reticulum Sagitta

p.414 p.425 p.381 p.390 p.392 p.386 p.370 p.417 p.420 p.388 p.404 p.409 p.408 p.420 p.382

18h 19h

17h

20h

Sagittarius Scorpius Sculptor Scutum Serpens (Caput and Cauda) Sextans Taurus Telescopium Triangulum Triangulum Australe Tucana Ursa Major Ursa Minor Vela Virgo Volans Vulpecula

p.400 p.402 p.404 p.382 p.380 p.396 p.372 p.416 p.369 p.414 p.418 p.360 p.354 p.410 p.378 p.422 p.384

ARA TELESCOPIUM NORMA

THE SOUTH POLAR SKY

15h

PAVO LUPUS TRIANGULUM AUSTRALE

INDUS

APUS

GRUS

14h

CIRCINUS 13h

CENTAURUS MUSCA OCTANS

CRUX -90

˚

-70

0

1

2

3

4

5

˚

-50

˚

12h

CHAMAELEON 11h

MENSA HYDRUS

10h

RETICULUM

DORADO

VELA

VOLANS

9h

CARINA

STAR MAGNITUDES -1

-60

˚

8h

PICTOR Variable star

Star magnitudes shown here are for the equatorial and polar sky charts

7h

5h 6h

T HE N I G H T S K Y

There is no PHOENIX southern equivalent TUCANA of Polaris, the north pole star—in fact, the area around the south celestial pole is remarkably barren. This chart shows the sky from declinations ERIDANUS -50° to -90°. Many of the stars on this chart are circumpolar for southern observers—that is, the stars HOROLOGIUM never set and are always visible in the night sky. The farther south the viewer, the greater the amount of sky that is circumpolar.

-80

˚

350

THE CONSTELLATIONS

EQUATORIAL SKY CHART 1 This part of the sky is best placed for observation on evenings in September, October, and November. It contains the vernal equinox, in Pisces, which is the point at which the Sun’s path, the ecliptic, crosses the celestial equator into the northern half of the sky. The Sun reaches this point in late March each year. The 0h line of right ascension also passes through this point; this is the celestial equivalent of 0° longitude (the prime meridian) on Earth. The most distinctive feature in this region of the night sky is the great Square of Pegasus— although one star in the square actually belongs to neighboring Andromeda. 21h

3h 50

50

˚

˚

22h

2h 1h

23h

0h

CASSIOPEIA PERSEUS 40

40

˚

˚

CYGNUS ANDROMEDA 30

˚

LACERTA 30

TRIANGULUM

˚

VULPECULA

20

ARIES

˚

20

PEGASUS

˚

DELPHINUS

EC

LIP

10

TIC

˚

PISCES

10

˚

0

˚

EQUULEUS 0

˚ CETUS ERIDANUS

-10

˚

-10

AQUARIUS -20

˚

-20

CAPRICORNUS PISCIS AUSTRINUS

SCULPTOR -30

-30

˚ FORNAX GRUS

PHOENIX

TH E N I G H T S KY

-40

˚

MICROSCOPIUM

0h

1h

ERIDANUS

23h

INDUS 22h

2h -50

˚

3h

21h

STAR MAGNITUDES -1

0

1

2

3

4

5

Variable star

Star magnitudes shown here are for the equatorial and polar sky charts

-50

˚

-40

˚

˚

˚

˚

MAPPING THE SKY

351

EQUATORIAL SKY CHART 2 This area of sky is best placed for observation on evenings in June, July, and August. It contains the point where the Sun reaches its most southerly declination each year, in Sagittarius. This happens around December 21, which is the longest day in the Southern Hemisphere and the shortest day in the Northern. Rich Milky Way star fields cross this region of sky, from Cygnus in the north to Sagittarius and Scorpius in the south. Hercules and Ophiuchus, both representing mythical giants, stand head to head in the north. Notable star patterns in the south are the Teapot asterism in Sagittarius and the curving tail of Scorpius, the Scorpion. 21h 50

15h 50

˚ 20h 19h

17h

18h

DRACO 40

˚

16h

BOOTES

˚

40

˚

LYRA

CYGNUS 30

CORONA BOREALIS

˚

30

˚

HERCULES VULPECULA 20

20

˚ DELPHINUS

10

˚

SERPENS CAPUT

SAGITTA

˚

10

˚

0

˚

AQUILA VIRGO OPHIUCHUS 0

˚ AQUARIUS

-10

˚

-20

SCUTUM SERPENS CAUDA

˚

-30

-10

LIBRA

˚

ECLIPTIC -20

CAPRICORNUS

SAGITTARIUS

˚

SCORPIUS

˚

-40

-50

˚

NORMA

18h

19h

17h

20h

16h -50

21h

15h

STAR MAGNITUDES -1

0

1

2

3

4

5

Variable star

Star magnitudes shown here are for the equatorial and polar sky charts

˚

˚

T HE N I G H T S K Y

ARA

TELESCOPIUM INDUS

˚

CORONA AUSTRALIS

MICROSCOPIUM

-40

-30

LUPUS

˚

352

THE CONSTELLATIONS

EQUATORIAL SKY CHART 3

This region is best placed for observation on evenings in March, April, and May. It contains the point at which the Sun moves across the celestial equator into the Southern Hemisphere each year. This point lies in Virgo, and the Sun reaches it around September 21. In the northern constellation Boötes lies Arcturus, a notably orange-colored star whose visibility marks the arrival of northern spring. South of it is the zodiacal constellation of Virgo, whose brightest star is the blue-white Spica. Adjoining Virgo is Leo, one of the few constellations that genuinely resembles the animal it is said to represent—in this case, a crouching lion. 15h 50

9h 50

˚ 14h 13h

11h

12h

URSA MAJOR 40

˚

10h

URSA MAJOR 40

˚

˚

CANES VENATICI LYNX 30

20

˚

30

LEO MINOR

˚

˚

CANCER

COMA BERENICES LEO

20

˚

TIC

LIP

10

EC

BOOTES

˚

10

˚

VIRGO 0

0

˚

˚

SEXTANS

-10

˚

-10

CORVUS

CRATER

LIBRA -20

˚

HYDRA

-20

PYXIS -30

˚

-30

ANTLIA

CENTAURUS

T HE N I G H T S K Y

-40

˚

-40

VELA LUPUS

12h

13h

11h 10h

14h -50

˚

-50 15h

9h

STAR MAGNITUDES -1

0

1

2

3

4

5

Variable star

Star magnitudes shown here are for the equatorial and polar sky charts

˚

˚

˚

˚

˚

MAPPING THE SKY

353

EQUATORIAL SKY CHART 4 This region is best placed for observation on December, January, and February evenings. It contains the point at which the Sun is farthest north of the celestial equator, on the border of Taurus with Gemini. This occurs around June 21, when days are longest in the northern hemisphere and shortest in the southern. Glittering stars and magnificent constellations abound in this region of sky, including the brightest star of all, Sirius in Canis Major. A distinctive line of three stars marks the belt of Orion, while in Taurus the bright star Aldebaran glints like the eye of the bull, along with the Hyades and Pleiades star clusters. 9h 50

3h

˚ 8h 7h

40

50

˚

4h 5h

6h

˚

40

˚

AURIGA PERSEUS

LYNX

30

30

˚ ARIES

GEMINI 20

˚

ECLIPTIC

˚

20

˚

CANCER 10

ORION

˚

10

TAURUS

CANIS MINOR 0

˚

˚

CETUS

0

HYDRA

˚

MONOCEROS -10

˚

-10

˚

ERIDANUS -20

˚

-20

LEPUS

˚

CANIS MAJOR

PYXIS

COLUMBA -30

PUPPIS

˚

-30

FORNAX

˚

CAELUM -40

VELA

-40

PICTOR 6h

7h

HOROLOGIUM

5h

8h -50

˚

9h

4h 3h

STAR MAGNITUDES -1

0

1

2

3

4

5

Variable star

Star magnitudes shown here are for the equatorial and polar sky charts

-50

˚

˚

TH E N I G HT S KY

˚

354

LONG-TAILED BEAR 2

The tail of the Little Bear curves away from the north Pole Star, Polaris (upper left). Unlike real bears, the celestial bears Ursa Minor and Ursa Major both have long tails.

Polaris

α

90

˚

δ

THE LITTLE BEAR

Ursa Minor SIZE RANKING

ε

56

80

BRIGHTEST STAR

Polaris (α) 2.0 GENITIVE

ABBREVIATION

ζ

η

Ursae Minoris

4

β

UMi

˚

5 70

Kochab

HIGHEST IN SKY AT 10 PM

γ

May–July

˚

Pherkad

FULLY VISIBLE

URSA MINOR

90°N–0°

TH E N I G H T S KY

THE NORTH POLE STAR 5

Ursa Minor is an ancient Greek constellation, which is said to represent Ida, one of the nymphs who nursed the god Zeus when he was an infant (see panel, right). Ursa Minor contains the north celestial pole and also its nearest naked-eye star, Polaris or Alpha (α) Ursae Minoris (see pp.278–79), which is currently less than one degree from the north celestial pole. The distance between them is steadily decreasing due to precession (see p.64). They will come closest around 2100, when the separation will be about 0.5 degrees. The main stars of Ursa Minor form a shape known as the Little Dipper, reminiscent of the larger and brighter Big Dipper in Ursa Major, although its handle curves in the opposite direction. The two brightest stars in the bowl of the Little Dipper, Beta (β) and Gamma (γ) Ursae Minoris, are popularly known as the Guardians of the Pole.

Seen through a small telescope, Polaris appears to have a faint companion (right), but this background star is unrelated. Its true companion is seen here just below Polaris.

SPECIFIC FEATURES Polaris, the north Pole Star, is a creamy white supergiant and a Cepheid variable (see p.282), but its brightness changes are too slight to be noticeable to the naked eye. With a telescope, an unrelated 8th-magnitude star can be seen nearby. Two stars in the bowl of the Little Dipper—Gamma and Eta Ursae Minoris—are both wide doubles. Gamma is the brighter of the two, at magnitude 3.0, and its 5th-magnitude companion, 11 Ursae Minoris, can be seen with the naked eye or binoculars. Eta—at magnitude 5.0— can also be seen with the naked eye. It has a partner of magnitude 5.5, 19 Ursae Minoris; both stars are easily visible with binoculars. Each of the component stars in both Gamma and Eta lie at different distances from the Earth and are thus unrelated.

60

DRACO THE LITTLE BEAR

MYTHS AND STORIES

NURSING NYMPHS According to Greek mythology, at his birth, the infant Zeus was hidden from his murderous father, Cronus, and taken to a cave on the island of Crete, where he was nursed by two nymphs, usually named as Adrastea and Ida. In gratitude, Zeus later placed the nymphs in the sky as the Great Bear and the Little Bear, respectively. THE PROTECTED CHILD

The infant Zeus is cared for by nymphs and shepherds, in the Feeding of Jupiter by the French artist Nicolas Poussin.

13h

17h 16h

15h

14h

˚

THE CONSTELLATIONS and is considered to be among the finest doubles visible with binoculars. Psi (ψ) Draconis is a somewhat closer pair, with components of 5th and 6th magnitudes, and requires a small telescope to be divided. More challenging to discern is Mu (μ) Draconis, with its two 6th-magnitude stars, which requires a telescope with high magnification to be seen as double. The wide pair of stars 16 and 17 Draconis is easily spotted with binoculars, and the brighter of the two—17 Draconis—can be further divided with a small telescope with high magnification, turning this into a triple star. A similar triple is 39 Draconis; when viewed with a small telescope with low magnification, it appears a double, but at higher magnification the brighter star divides into a closer pair with components of magnitudes 5.0 and 8.0. Two more doubles that can readily be seen with a small telescope are Omicron (ο) Draconis, with stars of 5th and 8th magnitudes, and 40 and 41 Draconis, which are both 6th-magnitude orange dwarfs. In central Draco lies a planetary nebula made famous by a striking Hubble Space Telescope image: NGC 6543, or the Cat’s Eye Nebula (see p.258). Processed in false color, the Hubble picture shows the nebula as red, but when seen through a small telescope it appears blue-green, as do all planetary nebulae.

THE DRAGON

Draco 8

SIZE RANKING

BRIGHTEST STAR

Etamin (γ) 2.2 GENITIVE

Draconis

ABBREVIATION

Dra

HIGHEST IN SKY AT 10 PM

April–August FULLY VISIBLE

90°N–4°S

One of the ancient Greek constellations, Draco represents the dragon of Greek myth that was slain by Hercules (see panel, below). This large constellation winds for nearly 180 degrees around the north celestial pole. Despite its size, Draco is not particularly easy to identify, apart from a lozenge shape marking the head. This is formed by four stars, including the constellation’s brightest member, Gamma (γ) Draconis, popularly known as Etamin or Eltanin. SPECIFIC FEATURES Double and multiple stars are a particular feature of Draco. Nu (ν) Draconis, the faintest of the four stars in the dragon’s head, is a readily identifiable pair. It consists of identical white components of 5th magnitude

355

BEAR AND DRAGON 2

The long body of Draco curls around the stars of Ursa Minor, the Little Bear. The head of the dragon is easily identifiable.

THE CAT’S EYE NEBULA 54

This amateur CCD image of NGC 6543 shows some of the color and structure captured by the Hubble Space Telescope, but visually the nebula appears as a blue-green ellipse. 80

70

˚

Polaris 90

˚

MYTHS AND STORIES

HERCULES AND THE DRAGON

˚ 10h

40, 41

CEPHEUS 60

˚

τ

ε

ρ

σ π

URSA MINOR

υ χ ϕ

δ

ψ

DRACO

ο

CYGNUS

39

α

18

ξ γ

ν β

URSA MAJOR

DRAGON KILLER

In this 16th-century painting by the Italian artist Lorenzo dello Sciorina, Hercules is depicted slaying the dragon by hand.

θ

12h

10

Thuban 13h

ι

μ THE DRAGON

16, 17

19h

BOOTES 18h

4

HERCULES 17h 16h

15h

14h

T HE N I G H T S K Y

Etamin

19

η

45

κ

15

ζ

NGC 6543

54

6

ω

42

20h

λ

1

The dragon Ladon guarded the golden apples that grew on Mount Atlas in the garden of Hera, wife of Zeus. As his twelth labor, the hero Hercules was required to steal some apples. To get to them, he killed the dragon with a poisoned arrow. Hera placed the dragon in the sky as the constellation Draco.

356

THE CONSTELLATIONS CEPHEUS

Cepheus 27

SIZE RANKING

BRIGHTEST STAR

Alpha (α) 2.5 GENITIVE

Cephei

ABBREVIATION

Cep

HIGHEST IN SKY AT 10 PM

September–October FULLY VISIBLE

90°N–1°S

IC 1396 4

The Garnet Star or Mu Cephei (top left) lies on the edge of the large but faint nebula IC 1396. The nebula is centered on the 6thmagnitude multiple star Struve 2816.

Cepheus lies in the far northern sky between Cassiopeia and Draco. Its main stars form a distorted tower or steeple shape, yet this ancient Greek constellation in fact represents the mythical King Cepheus of Ethiopia, who was the husband of Queen Cassiopeia and the father of Andromeda. Cepheus is not a particularly prominent constellation.

These changes can be followed with the naked eye. Delta (δ) Cephei is also a double star; its 6th-magnitude, blue-white companion is visible through a small telescope. A significant variable star of a different kind is Mu (μ) Cephei, which is a red supergiant that ranges anywhere between magnitudes 3.4 and 5.1 every two years or so. This supergiant is also known as the Garnet Star on account of its strong red coloration. Nonvariable stars near Delta (δ) and Mu (μ) Cephei can be used to gauge the magnitude of these two variable stars at any given time. For example, they can be compared to Zeta (ζ) at magnitude 3.4, Epsilon (ε) at magnitude 4.2, or Lambda (λ) Cephei at magnitude 5.1 (see chart, below).

SPECIFIC FEATURES The constellation’s most celebrated star is Delta (δ) Cephei (see p.286), from which all Cepheid variables take their name. Just under 1,000 lightyears away, this yellow-colored supergiant varies between magnitudes 3.5 and 4.4 every five days nine hours.

DRACO

90

˚ THE KING 2

URSA MINOR

80

11

TH E N I G H T S KY

CEPHEUS

β

24

CASSIOPEIA

˚

κ

γ

ο

Shaped like a bishop’s miter, Cepheus is not easy to pick out in the sky. He is flanked by his prominent wife, Cassiopeia, and Draco, the dragon.

DELTA (Δ) AND MU (Μ) CEPHEI

T

60

CEPHEUS

ι

ξ

VV

9

NGC 7160

δ

α

ε

ζ

ν

˚

22h 30m

θ

19

η

60

56

LACERTA 23h

22h

21h

Deneb

˚

i

c ¡

+ 14

DETERMINATION

1.0–1.9 2.0–2.9 3.0–3.9

13

Henrietta Swan Leavitt (18681921) worked at Harvard College Observatory in the early 20th century. Her study of variable stars in the Small Magellanic Cloud led to the period-luminosity law. This law links the variation period of a Cepheid variable to its intrinsic brightness, which in turn can indicate distance. Her law remains fundamental to our knowledge of the scale of the universe.

0.0–0.9

h b

IC 1396

NGC 7160

12

˚

μ

MAGNITUDE KEY

22h 00m

HENRIETTA LEAVITT

4.0–4.9 5.0–5.9 6.0–6.9

By painstakingly measuring photographic plates, Henrietta Leavitt discovered 2,400 variable stars of all types.

THE CONSTELLATIONS M103 15

CASSIOPEIA

M103’s main feature is a chain of three stars like a mini Orion’s belt. The northernmost member of the line (top) is not a true member of the cluster but lies closer to Earth.

Cassiopeia SIZE RANKING

25

Shedir (α) 2.2, Gamma (γ) 2.2 BRIGHTEST STARS

Cassiopeiae

GENITIVE

ABBREVIATION

Cas

HIGHEST IN SKY AT 10 PM

October–December FULLY VISIBLE

90°N–12°S

This distinctive constellation of the northern sky is found within the Milky Way between Perseus and Cepheus and north of Andromeda. The large W shape formed by its five main stars is easily recognizable. It is an ancient Greek constellation, representing the mythical Queen Cassiopeia of Ethiopia. SPECIFIC FEATURES Gamma (γ) Cassiopeiae (see p.285) is a hot, rapidly rotating star that occasionally throws off rings of gas from its equator, which causes unpredictable changes in its brightness. It has ranged between magnitudes 3.0 and 1.6, but it currently lies at magnitude 2.2, which makes it the joint brightest star in the constellation. A variable with a more predictable cycle is Rho (ρ) Cassiopeiae, an intensely luminous, yellow-white supergiant that fluctuates between 4th and 6th magnitudes every 10 or 11 months. It is estimated that it lies more than 10,000 light-years away, which is exceptionally distant for a naked-eye star.

Eta (η) Cassiopeiae is an attractive stellar pair consisting of a yellow and a red star. Its components are of magnitudes 3.5 and 7.5 and can be seen through a small telescope. This pair forms a true binary; the fainter companion orbits the brighter star every 480 years. Cassiopeia contains a number of open clusters within range of small instruments. Chief among them is M52 (see p.290), near the border with Cepheus. It is visible through binoculars as a somewhat elongated patch of light, and its individual stars—including a bright orange giant at one edge—can be seen through a small telescope. M103 is a small, elongated group, best viewed through a small telescope. Nearby is a larger cluster, NGC 663, which is more suitable for binocular observation. NGC 457 is a looser star cluster, containing the 5th-magnitude star Phi (φ) Cassiopeiae. This cluster’s appearance has been likened to an owl—its two brightest stars mark the owl’s eyes.

357

MYTHS AND STORIES

THE VAIN QUEEN Wife of Cepheus and mother of Andromeda, Queen Cassiopeia was notoriously vain. She enraged the Nereids, daughters of Poseidon, by boasting she was more beautiful. In punishment, Poseidon sent a seamonster to ravage her kingdom, which eventually led to the rescue of Andromeda by Perseus (see p.368). ETERNAL VANITY

The boastful queen is depicted sitting in a chair, fussing with her hair. Cassiopeia was condemned to circle the celestial pole, sometimes appearing to hang upside down in an undignified manner.

M52 15

Through binoculars, this cluster appears as a misty patch about one-third the diameter of a full moon. A telescope is needed to resolve its individual stars.

CASSIOPEIA

CEPHEUS

70

CASSIOPEIA

˚

50 48

ω

ι 60

˚

CAMELOPARDALIS

ε

IC?1805 IC?1848

NGC?663 M103

˚ PERSEUS

SN?1572

NGC?637

4 M52

NGC?559

γ κ 1 δ Cas?A τ χ υ1,2 β ρ NGC?7789 ϕ NGC? η Shedir 457 α σ λ θ ζ ν ξ ο

POLAR POINTER 2

π

ANDROMEDA 3h

LACERTA

0h

23h

The distinctive W shape formed by the main stars of Cassiopeia is easy to locate in the sky. The center of the W points toward the north celestial pole.

T HE N I G H T S K Y

50

ψ

THE CONSTELLATIONS THE GIRAFFE

Camelopardalis SIZE RANKING

18

BRIGHTEST STAR

Beta (β) 4.0 GENITIVE

Camelopardalis ABBREVIATION

Cam

HIGHEST IN SKY AT 10 PM

December–May FULLY VISIBLE

90°N–3°S

This dim constellation of the far northern sky, representing a giraffe, was introduced in the early 17th century on a celestial globe created by the Dutch astronomer Petrus Plancius (see panel, below). The giraffe’s long neck can be visualized as stretching around the north celestial pole toward Ursa Minor and Draco.

SPECIFIC FEATURES The brightest star in the constellation, Beta (β) Camelopardalis, is a double star whose fainter companion can be seen with a small telescope or even powerful binoculars. South of Beta (β) is 11 and 12 Camelopardalis, a wide double star with components of 5th and 6th magnitudes. Within the giraffe’s hindquarters is NGC 1502, a small open star cluster visible through binoculars or a small telescope. Binoculars also show a long chain of faint stars called Kemble’s Cascade, which lead away from NGC 1502 towards Cassiopeia. This star feature is named after Lucian Kemble, a Canadian amateur astronomer who first drew attention to it in the late 1970s. None of the stars, however, are actually related. NGC 2403 is a 9th-magnitude spiral galaxy that looks like a comet when seen through a small telescope. It is one of the brightest and closest galaxies to the Earth, outside the Local Group.

KEMBLE’S CASCADE 1

In an area five times the diameter of a full moon, the stars of Kemble’s Cascade seem to tumble down the sky. The small star cluster NGC 1502 can be seen in the lower left of the picture.

URSA MINOR

90

DRACO

˚

Polaris

THE GIRAFFE

CAMELOPARDALIS

70

γ

˚

NGC 2403

α

URSA MAJOR

60 NGC 1502

˚

β

LYNX 11,12

8h

7

7h

50

˚

PERSEUS AURIGA 6h

Capella

4h

NGC 2403 54

Color images of this galaxy reveal the pink glow of large emission nebulae in its spiral arms. It is about 11 million light-years away.

TH E NI G HT S KY

PETRUS PLANCIUS

PARTIAL VIEW 2

It can be difficult to relate the figure of a giraffe to the stars of Camelopardalis. Here, the stars of the giraffe’s legs are shown. The animal’s long neck would stretch off the top of the picture.

This Dutch church minister was also an expert geographer and astronomer. Petrus Plancius (1552–1622) taught the navigators on the first Dutch sea voyages to the East Indies how to measure star positions. In turn, they produced for him a catalog of the southern stars divided into 12 new constellations, which Plancius depicted on his celestial globes. He also invented several constellations, such as Columba, Camelopardalis, and Monoceros, using some of the fainter stars visible from Europe.

7h

THE CHARIOTEER

Auriga SIZE RANKING

21

BRIGHTEST STAR

Capella (α) 0.1 GENITIVE

Aurigae ABBREVIATION

Aur

HIGHEST IN SKY AT 10 PM

December–February FULLY VISIBLE

90°N–34°S

Auriga is easily identified in the northern sky by the presence of Capella (α), the most northerly firstmagnitude star. Auriga lies in the Milky Way between Gemini and Perseus, to the north of Orion. The constellation represents a charioteer. SPECIFIC FEATURES Auriga’s outstanding feature is a chain of three large and bright open star clusters. All three will just fit within the same field of view in wide-angle binoculars. Of the trio, M38’s stars are the most scattered and, when viewed with a small telescope, seem to form chains. The middle cluster is M36, the smallest cluster but also the easiest to spot, while M37 is the largest and contains the most stars, but these are faint. All three clusters lie about 4,000 light-years away. The star-forming nebula IC 405 is located nearby. Bright light from 6thmagnitude AE Aurigae near its center lights up the surrounding gases.

THE LYNX

Lynx SIZE RANKING

28

BRIGHTEST STAR

Alpha (α) 3.1 GENITIVE

Lyncis ABBREVIATION

Lyn

HIGHEST IN SKY AT 10 PM

February–March FULLY VISIBLE

90°N–28°S

Auriga also contains two extraordinary eclipsing binaries of long period. One is Zeta (ζ) Aurigae, which is an orange giant orbited by a smaller blue star that eclipses it every 2.7 years. This causes a 30 percent decrease in brightness for six weeks, from magnitude 3.7 to 4.0. More remarkable, however, is Epsilon (ε) Aurigae (see p.281). This intensely luminous giant star is orbited by a mysterious dark partner that eclipses it every 27 years—the longest interval of any eclipsing binary. During the eclipse, Epsilon’s brightness is halved, from magnitude 3.0 to 3.8, and it remains dimmed for more than a year. Astronomers think that its companion star is enveloped in a disk of dust seen almost edge-on. The last eclipse occurred between 2009 and 2011. The next is due to start in 2036.

THE CHARIOTEER

δ 50

ξ PERSEUS 9

˚ ψ1

40

ψ7 ψ

˚

AURIGA

β

2

Capella

π

UU

θ

ν τ υ

Castor

˚

RT Pollux

κ

η

NGC 1664

ζ

M38 NGC 1907 AE IC 405

χ

GEMINI

ε μ

M36

30

α λ

NGC 2281

63

16

4 2

ι

M37

Alnath

β Tau TAURUS

SHARED STAR 2

Neighboring Beta (β) Tauri completes the charioteer figure. Auriga is usually identified as a king of Athens, Erichthonius.

THE FLAMING STAR NEBULA 54

AE Aurigae is a hot, massive star of magnitude 6 that lights up the surrounding cloud of gas and dust that is the Flaming Star Nebula, IC 405.

SPECIFIC FEATURES Lynx contains many interesting double and multiple stars. For example, 12 Lyncis appears double with a small telescope, but with a telescope of 3 in (75 mm) or larger aperture the brighter star divides into two components of 5th and 6th magnitudes, which have an orbital period of about 700 years. An easier triple to identify is 19 Lyncis. This consists of two stars of 6th and 7th magnitudes and a wider 8th-magnitude companion, all visible through a small telescope. A more challenging

double star is 38 Lyncis, with components of 4th and 6th magnitudes. A telescope of 3-in (75-mm) aperture is required to separate the individual stars. 6h 7h

8h

12 24

2

15 19

27

LYNX

URSA MAJOR

21 16

40

˚

10 UMa

31 NGC 2419

38

α 30

THE LYNX

Castor

˚

GEMINI CANCER

Pollux

ELUSIVE FELINE 2

Lynx consists of nothing more than a few faint stars zigzagging between Ursa Major and Auriga. To spot it, sharp eyesight or binoculars are required.

TH E N I G HT S KY

Lynx is a fair-sized but faint constellation in the northern sky. It was introduced in the late 17th century by Johannes Hevelius (see p.384), who wanted to fill the gap between Ursa Major and Auriga. Hevelius is reputed to have named it Lynx because only the lynx-eyed would be able to see it— Hevelius himself had very sharp eyesight. The animal he drew on his star chart, however, looked little like a real lynx.

6h

LYNX

360

THE CONSTELLATIONS the Big Dipper points toward the bright star Arcturus in the adjoining constellation of Boötes.

THE GREAT BEAR

Ursa Major SIZE RANKING

SPECIFIC FEATURES The Big Dipper is one of the most famous patterns in the sky. Its shape is formed by the stars Dubhe (α), Merak (β), Phad (γ), Delta (δ) Ursae Majoris, Alioth (ε), Mizar (ζ) (see p.276), and Alkaid (η). With the exception of Dubhe and Alioth, these stars travel through space in the same direction, and they form what is known as a moving cluster. Mizar (ζ), the second star in the Big Dipper’s handle, is next to Alcor (see p.276), an eighth, fainter star in the Big Dipper, which can be seen with good eyesight. A small telescope reveals that Mizar also has a closer 4th-magnitude companion. In southern Ursa Major lies a more difficult double star, Xi (ξ) Ursae Majoris, which needs a telescope with an aperture of 3 in (75 mm) to divide it. This pair, with components of 4th and 5th magnitudes, forms a true

3

BRIGHTEST STARS

Alpha (α) 1.8, Epsilon (ε) 1.8. GENITIVE

Ursae

Majoris ABBREVIATION

binary relationship, orbiting every 60 years, which is quick by the standards of visual binary stars. One of the easiest galaxies to identify with binoculars is M81, which is in northern Ursa Major, and is also known as Bode’s Galaxy (see p.314). This spiral galaxy is at an angle and can be seen on clear, dark nights as a slightly elongated patch of light. A telescope is needed to spot the rather more elongated shape of the smaller and fainter Cigar Galaxy (see p.314), or M82, which is found one diameter of a full moon away from Bode’s Galaxy. This unusual-looking object is now thought to be a spiral galaxy, seen edge-on, mottled with dust clouds and undergoing a burst of star formation following an encounter with M81. Another major spiral galaxy in this constellation is the Pinwheel Galaxy, M101 (p.316), which lies near the end of the Big Dipper’s handle. Though larger than Bode’s Galaxy, it is fainter and thus more difficult to see. An even greater challenge to find and

UMa

HIGHEST IN SKY AT 10 PM

February–May FULLY VISIBLE

90˚N–16˚S

Ursa Major is one of the best-known constellations and a prominent feature of the northern sky. Seven of its stars form the familiar shape of the Big Dipper. But as a whole, Ursa Major is much larger than this; it is the thirdlargest constellation in the sky. The two stars in the Big Dipper’s bowl farthest from the handle, Dubhe (α) and Merak (β), point toward the north Pole Star, Polaris, while the curved handle of

THE OWL NEBULA 54

The dark, owl-like eyes of the faint planetary nebula M97 are visible only through large telescopes or on photographs and CCD images such as this one.

identify, however, is the Owl Nebula, or M97, located under the bowl of the Big Dipper. This planetary nebula is one of the faintest objects in Charles Messier’s catalog, and a telescope of around 3 in (75 mm) aperture is needed to make out its gray-green disk, which is three times larger than that of Jupiter. A telescope with an even larger aperture reveals the two dark patches, like an owl’s eyes, that give rise to its popular name.

THE CIGAR GALAXY 54

M82 is a peculiar-looking spiral galaxy, edge-on to us, that is undergoing a burst of star formation triggered by a close encounter with the larger and brighter spiral galaxy M81 about 300 million years ago.

THE GREAT BEAR

8h 9h

13h

10h

70

12h

ρ

24

M82

M81

DRACO

σ

M101

83

δ

Alcor 78

ζ

Mizar

ε

α

BOOTES

υ

γ

36

ϕ

β

M97

θ

ψ

40

ω

ν

ι

λ

56

˚

15

κ

55

COMA BERENICES

18

26

χ CANES VENATICI

ο

50 Merak

Phad M109

η

TH E NI G H T S KY

Dubhe

M108

˚

23

THE BIG DIPPER

Alioth

Alkaid

60

π2 τ

URSA MAJOR

˚

˚

LYNX

μ LEO MINOR

30

ξ LEO

˚

BODE’S GALAXY 54

This spiral galaxy was discovered by German astronomer Johann Elert Bode on December 31, 1774. Located approximately 11 million light-years away, M81 is nevertheless one of the brightest and most visible galaxies in the sky.

THE CONSTELLATIONS

361

THE HIDDEN DOUBLE 21

Although Mizar (ζ) and its neighbor Alcor may appear to be a double star when seen with the naked eye (see main picture), upon further magnification, Mizar (on the left of this image) is revealed to have an even closer companion than Alcor (on the right).

A FAMILIAR SIGHT 2

The saucepan shape of the Big Dipper’s stars is one of the most easily recognized sights in the night sky, but it makes up only part of the whole constellation pattern of Ursa Major.

MYTHS AND STORIES

THE TALE OF THE GREAT BEAR

RECURRING PATTERN

The shape of the Big Dipper can be seen clearly (below, center) on this northern polar chart from Dunhuang, China, dating from AD 940 or earlier.

TH E N I G HT S KY

The Big Dipper is one of the oldest, most recognized patterns in the sky. In Greek myth, it represents the rump and long tail of the Great Bear. Two characters are identified with it: Callisto, who was one of Zeus’s lovers (see p.187); and Adrastea, a nymph who nursed the infant Zeus and was later placed in the sky as the Great Bear.

362

THE CONSTELLATIONS

12h

14h

13h

URSA MAJOR

THE HUNTING DOGS

Canes Venatici SIZE RANKING

50

38

˚

5

BRIGHTEST STAR

24

Cor Caroli (α) 2.9

NGC 5195

Canum Venaticorum

M106

GENITIVE

ABBREVIATION

M51

Y

NGC 4449

CVn M63

HIGHEST IN SKY AT 10 PM

40

April–May

M94

˚

20

α

FULLY VISIBLE

90°N–37°S

β

Cor Caroli

25

Canes Venatici lies in the northern sky between Boötes and Ursa Major. This constellation represents two dogs held on a leash by the herdsman Boötes. It was formed by Johannes Hevelius (see p.384) at the end of the 17th century from stars that had previously been part of Ursa Major. SPECIFIC FEATURES The constellation’s brightest star, Alpha (α) Canum Venaticorum, is known as Cor Caroli, meaning Charles’s Heart, in commemoration of King Charles I of England. This wide double star, with components of magnitudes 2.9 and 5.6, is easily separated with a small telescope. The brighter star is slightly variable, by about one-tenth of a magnitude, which is too small to be noticeable to the naked eye. Larger variation is found in Gamma (γ) Canum Venaticorum, a deep red supergiant popularly known as La Superba. It fluctuates between magnitudes 5.0 and 6.5 every 160 days or so.

THE WHIRLPOOL GALAXY 54

30

The core of this beautiful spiral galaxy (also known as M51) appears as a point of light in a small telescope, as does its companion galaxy NGC 5195 (top) at the end of one arm.

Canes Venatici also contains some fine galaxies, such as the Whirlpool Galaxy (see p.315), or M51, which is found seven diameters of a full moon from the star at the end of the handle of the Big Dipper (in Ursa Major). The Whirlpool Galaxy was the first galaxy in which spiral form was detected— the observation being made in 1845 by William Parsons (see p.315) in Ireland. The galaxy appears as a round patch of light through binoculars, but a moderate-sized telescope is needed to make out the spiral arms. At the end of one of the arms lies a smaller galaxy, NGC 5195, which is passing close to M51. Two spiral galaxies worth looking for through a small telescope are the Sunflower Galaxy (M63) and M94.

CANES VENATICI

˚

NGC 4631

M3

BOOTES

20

COMA BERENICES

˚ Arcturus

THE HUNTING DOGS

THE SUNFLOWER GALAXY 54

TH E N I G H T S KY

M63 is a spiral galaxy, with patchy outer arms, that is seen at an angle from Earth. The arms give rise to comparisons with the appearance of a sunflower. The star to its right in this photograph is of 9th magnitude.

TWO BRIGHT STARS 2 GLOBULAR CLUSTER M3 15

This cluster is one of the biggest and brightest globular clusters in the northern sky. A telescope with a 4-in (100-mm) aperture is needed to resolve its individual stars.

Canes Venatici represents a pair of hounds, but the unaided eye can see little more than the constellation’s brightest stars, Cor Caroli and Beta Canum Venaticorum.

THE CONSTELLATIONS binoculars. In billions of years, our Sun will swell into a red giant similar to this star. Boötes is noted for its double stars, the most celebrated of which is Izar (see p.277), or Epsilon (ε) Boötis, at the heart of the constellation. To the naked eye, it appears of magnitude 2.4, but high magnification on a telescope of at least 3 in (75 mm) aperture reveals a close, 5th-magnitude companion that is blue-green in color, providing one of the most beautiful contrasts of all double stars. Much easier to divide with any small telescope are Kappa (κ) and Xi (ξ) Boötis. Kappa’s stars, with components of 5th and 7th magnitudes, are unrelated, but Xi, with stars also of 5th and 7th magnitudes, is a true binary with an orbital period of 150 years and has warm yellow-orange hues. Easiest of all are the doubles Mu (μ) Boötis, with components of 4th and 6th magnitudes, and Nu (ν) Boötis, with two 5th-magnitude components—both are widely spaced enough to divide with binoculars.

THE HERDSMAN

Boötes 13

SIZE RANKING

BRIGHTEST STAR

Arcturus (α) -0.1 GENITIVE

Boötis

ABBREVIATION

Boo

HIGHEST IN SKY AT 10 PM

May–June FULLY VISIBLE

90°N–35°S

The Greek constellation Boötes contains the brightest star north of the celestial equator, Arcturus—Alpha (α) Boötis—which is also the fourthbrightest star in the entire sky. This large and conspicuous constellation extends from Draco and the handle of the Big Dipper (in Ursa Major) to Virgo. Faint stars in the northern part of Boötes once formed the nowdefunct constellation of Quadrans Muralis, which gave its name to the Quadrantid meteor shower that radiates from this area every January.

363

MYTHS AND STORIES

THE BEAR-KEEPER Boötes represents a man herding a bear (Ursa Major). Myths differ as to whether he is a hunter or a herdsman, as the constellation’s brightest star, Arcturus, means “bear guard” or “bear-keeper” in Greek. The man’s two dogs are represented by adjoining Canes Venatici. In Greek myth, Boötes was identified with Arcas, son of Zeus and Callisto. ADJACENT STARS

Boötes is depicted here leading the two hunting dogs, on an 18th-century star chart by Sir James Thornhill. DOUBLE STAR IZAR 5

Epsilon (ε) Boötis, which is also known as Izar or Pulcherrima, is a challenging double star consisting of a bright orange star with a fainter blue-green companion star.

THE HERDSMAN

SPECIFIC FEATURES Arcturus is classified as a red giant, but as with most supposedly “red” stars, it actually looks orange to the unaided eye. Its coloring becomes stronger when viewed through

16h

14h

15h

50

κ2

θ

˚

ι

44

HERCULES 40

BOOTES

˚

ν

β γ

μ

30

˚

URSA MAJOR

λ

CORONA BOREALIS

δ ρ ψ

ε ω

COMA BERENICES

σ Izar

12

45 6

˚

ξ

π

ο SERPENS CAPUT

ζ

α

η Arcturus

20

τ

υ KITE-SHAPED CONSTELLATION 2

31

Boötes, containing the bright star Arcturus, stands aloft in spring skies in the Northern Hemisphere. The crown of Corona Borealis can be seen to its left.

T HE N I G H T S KY

20

364

THE CONSTELLATIONS The most distinctive feature of this constellation is a quadrilateral of stars called the Keystone, which is composed of Epsilon (ε), Zeta (ζ), Eta (η), and Pi (π) Herculis.

HERCULES

Hercules SIZE RANKING

5

BRIGHTEST STAR

SPECIFIC FEATURES Alpha (α) Herculis, (see p.285), or Rasalgethi, is actually the secondbrightest star in Hercules. It fluctuates between 3rd and 4th magnitudes. As with most such erratic variables, Rasalgethi is a bloated red giant that pulsates in size, causing the brightness changes. A small telescope brings a 5th-magnitude blue-green companion star into view. On one side of the Keystone lies M13, which is regarded as the finest globular cluster of northern skies. Under ideal conditions, M13 can be glimpsed with the naked eye, and through binoculars it appears like a hazy star half the width of a full moon. Slightly farther away from the Keystone is a second globular cluster— M92. This often overlooked cluster is smaller and fainter than M13, and when seen through binoculars it can easily be mistaken for an ordinary star. Several readily seen double stars are to be found in Hercules, including Kappa (κ) Herculis, with components of 5th and 6th magnitudes, and 100 Herculis, with its two 6thmagnitude stars. Positioned closer together, and hence requiring higher magnification, are 95 Herculis, with two 5th-magnitude components, and Rho (ρ) Herculis, with components of 5th and 6th magnitudes.

Kornephoros (β) 2.8 GENITIVE

Herculis

ABBREVIATION

Her

HIGHEST IN SKY AT 10 PM

June–July FULLY VISIBLE

90°N–38°S

This large but not particularly prominent constellation of the northern sky represents Hercules, the strong man of Greek myth. In the sky, Hercules is depicted clothed in a lion’s pelt, brandishing a club and the severed head of the watchdog Cerberus, and kneeling with one foot on the head of the celestial dragon, Draco—the tools and conquests of some of his 12 labors.

HERCULES

UPSIDE DOWN 2

In the night sky, Hercules is positioned with his feet pointing toward the pole (top left in this picture) and his head pointing south.

16h

DRACO 50

17h

18h

˚ 42

ι

Vega

π

KEYSTONE

68 104

ο

ν

ξ

100 109

TH E NI G HT S KY

110 111

106 95

λ

BOOTES

M13

ζ

ε μ

GLOBULAR CLUSTER M13 15

η

ρ 69 θ

χ

30

M92

˚

113

ϕ

σ

LYRA 40

υ

τ

52

Through binoculars, this cluster appears as a rounded patch of light. It breaks up into countless starry points when viewed through a small telescope.

CORONA BOREALIS

δ NGC 6210

HERCULES

β γ

102

CLUSTER ABELL 2151

93 Rasalgethi

α

κ

ω

60 29

OPHIUCHUS SERPENS CAPUT

THE HERCULES GALAXY CLUSTER 3

Every fuzzy object in this picture is a faint galaxy in the cluster Abell 2151, some 500 million light-years away.

THE CONSTELLATIONS THE LYRE

Lyra SIZE RANKING

52

BRIGHTEST STAR

Vega (α) 0.0 GENITIVE

Lyrae

ABBREVIATION

Lyr

HIGHEST IN SKY AT 10 PM

July–August FULLY VISIBLE

90°N–42°S

Lyra lies on the edge of the Milky Way next to Cygnus and is a compact constellation of the northern sky. It includes Vega, or Alpha (α) Lyrae (see p.253), which is the fifth-brightest star in the sky and one of the so-called Summer Triangle of stars—the other two being Deneb (in Cygnus) and Altair (in Aquila). The Lyrid meteors radiate from a point near Vega around April 21–22 every year. Lyra represents the stringed instrument played by Orpheus (see panel, below). SPECIFIC FEATURES Vega dazzles at magnitude 0.0, appearing somewhat blue-white in color to the unaided eye. It is the

standard star against which astronomers compare the color and brightness of all other stars. The finest quadruple star in the sky—Epsilon (ε) Lyrae (see p.276)— is found three diameters of a full moon from Vega. Binoculars easily show it as a neat pair of 5thmagnitude white stars, but each of these has a closer companion that is brought into view with a telescope of 2.5–3 in (60–75 mm) aperture and high magnification. All four stars are linked by gravity and are in longterm orbit around each other. Two other double stars near Vega that are easy to identify with binoculars are Zeta (ζ) and Delta (δ) Lyrae, each with components of 4th and 6th magnitudes. Beta (β) Lyrae is another double star, easily resolved by a small telescope into its cream and blue components. The brighter star (the cream one) is an eclipsing binary that fluctuates between magnitudes 3.3 and 4.4 every 12.9 days. Many years of study have established that Beta’s two stars are so close that gas from the larger of the pair falls toward the smaller companion, and some of it spirals off into space. Almost midway between Beta

and Gamma (γ) Lyrae lies the most photographed of Lyra’s celestial treasures, the Ring Nebula (see p.257), or M57. This planetary nebula is shaped like a smoke ring, and appears through a small telescope as a disk larger than that of Jupiter. Larger apertures are needed to make out the central hole. Studies with the Hubble Space Telescope have revealed that the “ring” is in fact a cylinder of gas thrown off from the central star, oriented almost end-on to the Earth.

365

18h

19h

CYGNUS LYRA

R RR 40

30

˚

ε1,2

η

δ1,2

θ

˚

γ

β

λ

M57

α

Vega

ζ1

κ

M56

THE LYRE

HERCULES VULPECULA

THE RING NEBULA 4

One of the most famous planetary nebulae in the whole sky, the Ring Nebula, or M57, consists of hot gas shed from a central star. Its beautiful colors are revealed only on photographs such as this one. MYTHS AND STORIES

ORPHEUS

ENTRANCED

Orpheus was said to have charmed even the rocks and streams with his music. In this 19th-century painting, he tames the wild animals with his songs.

STRINGED INSTRUMENT 2

Lyra, dominated by dazzling Vega, represents the harp played by Orpheus, the musician of Greek myth. Arab astronomers visualized the constellation as an eagle or vulture.

T HE N I G H T S K Y

Heartbroken Orpheus descended into the Underworld to retrieve his wife, Eurydice, who had been killed by a snake. His songs charmed Hades, god of the Underworld, who agreed to release Eurydice provided Orpheus did not look back as he led her to the surface. At the last minute, Orpheus glanced behind him, and Eurydice faded away. Orpheus then roamed the Earth, disconsolately playing his lyre.

366

THE CONSTELLATIONS

Cygnus SIZE RANKING

SPECIFIC FEATURES Cygnus’s brightest star, Deneb—Alpha (α) Cygni—lies in the tail of the swan, or at the top of the cross, depending on how the constellation is visualized. Deneb is an immensely luminous supergiant star located about than 1,400 light-years away, making it the most distant 1st-magnitude star. It forms one corner of the northern Summer Triangle—a familiar sight in the skies of northern summers and southern winters—which is completed by Vega (in Lyra) and Altair (in Aquila). The beak of the swan (or the foot of the cross) is marked by a double star, Beta (β) Cygni, known as Albireo. Its two stars are sufficiently

Deneb (α) 1.2 GENITIVE

Cygni

ABBREVIATION

Beta (β) Cygni, also known as Albireo, marks the beak of the swan. This double star, with its strikingly contrasting colors, is easily separated with a small telescope.

16

BRIGHTEST STAR

Cyg

HIGHEST IN SKY AT 10PM

August–September FULLY VISIBLE

90˚N–28˚S

Situated in a rich area of the Milky Way, Cygnus is one of the most prominent constellations of the northern sky and contains numerous objects of interest. The relatively large constellation depicts a swan in flight,

far apart that they can be seen separately with ordinary binoculars, if steadily mounted, and they are easy targets for a small telescope. The brighter star, of magnitude 3.1, is orange, and the fainter star, magnitude 5.1, is blue-green. A similar color difference is evident between Omicron-1 (ο1)

THE SWAN

19h

22h 60

ALBIREO 5

but its main stars are arranged in the shape of a giant cross, hence its alternative popular name of the Northern Cross.

THE SWAN

20h

21h

˚ CEPHEUS 33

LACERTA 50

˚

π

CYGNUS

2

π

63

M39

40

˚

ξ

NGC 7000

72

σ υ

30

˚

1

μ

57

α ο1

61

ζ

30

γ

δ Vega

22 15

P

ε

47

29 28 Cyg X-1

NGC 6992 39

52

LYRA

Cyg A

M29

λ

ι

θ

Deneb

ν

τ

NGC 6826

ο2

ω1

59

55

ρ

W

κ

ψ

1

41

η χ

8 17

ϕ

Albireo

PEGASUS

TH E N I G H T S KY

VULPECULA

POISED IN FLIGHT 2

Among the stars of Cygnus, it is comparatively easy to visualize a swan, with its wings outstretched, as it flies along the Milky Way.

β2 HERCULES

Cygni, a 4th-magnitude orange star, and its wide 5th-magnitude companion, 30 Cygni, which has a noticeable bluish color when seen through binoculars. A 7th-magnitude star, again bluish, and even closer to Omicron-1, can also be seen with binoculars or a small telescope. Another pair of stars that is easy

THE CONSTELLATIONS to spot with a small telescope is 61 Cygni (see p.252), which consists of two orange dwarfs of 5th and 6th magnitudes that orbit each other every 650 years. A large open star cluster, M39, covers an area of sky of similar size to a full moon near the constellation’s border with Lacerta. On clear nights, the Milky Way appears as a hazy band of light running through Cygnus, divided in two by an intervening cloud of dust known as the Cygnus Rift or the Northern Coalsack. The rift continues, via Aquila, into Ophiuchus. Two large and remarkable nebulae are found in Cygnus, although neither is easy to identify. The glowing gas cloud of the North America Nebula (NGC 7000), near Deneb, can be glimpsed

through binoculars on clear, dark nights, but its full majesty becomes apparent only on long-exposure photographs or CCD images. The Veil Nebula is a diffuse nebula found in the wing of the swan. Again, it is best seen on photographs, although the brightest part—NGC 6992—can just be made out with binoculars or a small telescope and becomes more prominent with the addition of filters to the telescope. Considerably smaller, but much easier to spot, is the Blinking Planetary (NGC 6826) in the other wing of the swan, with a

367

MYTHS AND STORIES

LEDA AND THE SWAN The swan represents the disguise adopted by Zeus for an illicit love tryst. The object of his desire is sometimes said to have been a nymph called Nemesis or, in a more popular version, Queen Leda of Sparta. After her union with Zeus, Leda is said to have given birth to either one or two eggs, according to different versions of the story, from which hatched Castor, Pollux, and their sister Helen of Troy. Pollux and Helen were reputedly the offspring of Zeus, but Castor was the son of Leda’s husband, King Tyndareus. FAMILY GROUPING

Queen Leda, the twins Castor and Pollux, and the swan are captured in this painting after the original by Leonardo da Vinci.

OPEN CLUSTER M39 15

M39 is the larger and brighter of the two Messier clusters in Cygnus and contains around 30 members arranged in a triangular shape, with a double star near the center. It lies 900 light-years away and is easily spotted with binoculars. Under good conditions, M39 is visible to the naked eye.

blue-green disk similar in size to that of Jupiter. It is popularly known as the Blinking Planetary because of an odd optical effect in which, as the observer looks alternately directly at it and off to one side, it appears to blink on and off. Two objects of considerable astrophysical interest in Cygnus are beyond the reach of amateur observers. Cygnus A (see p.324) is a powerful radio source, the result of two galaxies in collision millions of light-years away. Cygnus X-1 (see p.272), near Eta (η) Cygni, is an intense X-ray source, thought to be a black hole orbiting a 9th-magnitude blue supergiant in our galaxy. NORTH AMERICA NEBULA 154

In the tail of the swan lies NGC 7000, which is popularly known as the North America Nebula, on account of its similarity in shape to that continent.

Splashed across an area wider than six full moons is the Veil Nebula, a loop of gas that is the remains of a star that exploded as a supernova thousands of years ago.

TH E N I G HT S KY

VEIL NEBULA 54

368

THE CONSTELLATIONS ANDROMEDA

Andromeda SIZE RANKING

19

constellation Pegasus, where it marked the navel of the horse. The star’s two names—Alpheratz and Sirrah—are both derived from an Arabic term that means “the horse’s navel.”

BRIGHTEST STARS

Alpheratz (α) 2.1, Mirach (β) 2.1 GENITIVE

Andromedae ABBREVIATION

And

HIGHEST IN SKY AT 10 PM

October–November FULLY VISIBLE

90°N–37°S

This celebrated constellation of the northern skies depicts the daughter of the mythical Queen Cassiopeia, who is represented by a neighboring constellation. The head of the princess is marked by Alpheratz (or Sirrah )— Alpha (α) Andromedae—which is the star at the nearest corner of the Square of Pegasus, in another adjacent constellation. Long ago, Alpheratz was regarded as being shared with the

field of view and to concentrate the light. The small companion galaxies, M32 and M110, are difficult to see through a small telescope. Gamma (γ) Andromedae, known also as Almaak or Almach (see p.277), is a double star of contrasting colors. It consists of an orange giant star of magnitude 2.3 and a fainter blue companion, and it is easily seen through a small telescope.

SPECIFIC FEATURES On a clear night, the farthest it is possible to see with the naked eye is about 2.5 million light-years, which is the distance to the Andromeda Galaxy (see pp.312–313), a huge spiral of 2h stars similar to our own galaxy. PERSEUS Also known as M31, this 50 ˚ galaxy spans several diameters of a full moon and lies high 65 in the mid-northern sky on 51 fall evenings. The naked eye sees it as a faint patch; it looks elongated, ξ 60 rather than spiral, ω Almach because it is tilted at a 40 γ1 ˚ steep angle toward NGC 891 υ the Earth. When τ looking at M31 58 through a NGC 752 telescope, low magnification β must be used to 30 give the widest ˚

23h 1h

0h

3 8

ϕ ψ ν

M110

LACERTA

ANDROMEDA

σ

Mirach

ο

NGC 7662

θ

μ

7

λ κ ι

M31 M32

π

TRIANGULUM

δ

THE BLUE SNOWBALL 54

When seen through a small telescope, NGC 7662 appears as a bluish disk. Its structure is brought out only on CCD images such as this one.

The open star cluster NGC 752 spreads over an area larger than a full moon and can be identified with binoculars, but a small telescope is needed to resolve its individual stars of 9th magnitude and fainter. NGC 7662, which is popularly known as the Blue Snowball, is one of the easiest planetary nebulae to identify, and it can be found through a small telescope.

ε η ζ

α

Alpheratz

PEGASUS

PISCES THE ANDROMEDA GALAXY 4

Only the inner parts of M31 are bright enough to be seen with small instruments. CCD images such as this bring out the full extent of the spiral arms. Below M31 on this image lies M110, while M32 is on its upper rim.

ANDROMEDA MYTHS AND STORIES

HEROIC RESCUE According to Greek mythology, Andromeda was chained to a rock on the seashore and offered as a sacrifice to a sea monster in atonement for the boastfulness of her mother, Queen Cassiopeia. The Greek hero Perseus, flying home after slaying Medusa, the Gorgon, noticed the maiden’s plight. He responded by swooping down in his winged sandals and killing the sea monster. He then whisked Andromeda to safety and married her. DAMSEL IN DISTRESS

TH E N I G H T S KY

The Flemish artist Rubens added the flying horse Pegasus to his 17th-century depiction of Andromeda’s dramatic rescue by Perseus from captivity on the rock.

HEAD TO TOE 2

Andromeda is one of the original Greek constellations. Its brightest stars represent the princess’s head (α), her pelvis (β), and her left foot (γ).

THE CONSTELLATIONS THE LIZARD

Lacerta SIZE RANKING

68

BRIGHTEST STAR

Alpha (α) 3.8 GENITIVE

Lacertae ABBREVIATION

0h

to be a peculiar 14th-magnitude variable star, has given its name to a class of galaxies with active nuclei called BL Lac objects or “blazars.” A BL Lac object is a type of quasar that shoots jets of gas from its center directly toward the Earth. Because we see these jets of gas head-on, these BL Lac objects tend to look starlike.

23h

22h

THE LIZARD

CEPHEUS

50

˚

β

9

4

α

Lac

NGC 7243

5

2

HIGHEST IN SKY AT 10 PM

11

September–October FULLY VISIBLE

15

ANDROMEDA

90°N–33°S

6

BL

10

LACERTA

Lacerta consists of a zigzag of faint stars in the northern sky, squeezed between Andromeda and Cygnus like a lizard between rocks. It is one of the seven constellations invented by Johannes Hevelius (see p.384) during the late 17th century. This constellation contains no objects of note for amateur astronomers, although BL Lacertae (see p.325), which was once thought

30

THE TRIANGLE

Triangulum

40

˚

PEGASUS

2h

PERSEUS

78

BRIGHTEST STAR

ANDROMEDA

Beta (β) 3.0 GENITIVE

Trianguli

ABBREVIATION

1

CYGNUS

˚

3h

SIZE RANKING

369

R

Tri 30

HIGHEST IN SKY AT 10 PM

November–December

˚

β

γ δ 6

α

M33

TRIANGULUM

FULLY VISIBLE

90°N–52°S

ARIES 20

This small northern constellation is to be found lying between Andromeda and Aries. It consists of little more than a triangle of three stars. Triangulum is one of the constellations known to the ancient Greeks, who visualized it as the Nile delta or the island of Sicily.

THE TRIANGLE

TRIANGULUM AND MARS 2

This image of the three stars that make up the shape of Triangulum also includes the planet Mars, passing through neighboring Pisces.

M33 54

The clouds of pinkish gas in the arms of M33 show up in CCD images of this spiral galaxy in the Local Group. It is presented almost face-on to the Earth.

T HE N I G H T S K Y

SPECIFIC FEATURES Triangulum contains the third-largest member of our Local Group of galaxies, M33 or the Triangulum Galaxy (see p.311). In physical terms, M33 is about one-third the size of the Andromeda Galaxy, or M31 (see pp.312–13), and is much fainter. The spiral galaxy M33 appears as a large pale patch of sky. It is similar in size to a full moon, when viewed through binoculars or a small telescope on a dark, clear night. To see the spiral arms, a large telescope is needed. M33 looks like a starfish on long-exposure photographs. There is little else of note in the constellation apart from 6 Trianguli. This yellow star has a magnitude of 5.2 and has a 7th-magnitude companion that can be detected through a small telescope.

PISCES

˚

370

THE CONSTELLATIONS of the pair drops to just one-third its normal value, a change that is readily noticeable to the naked eye. Algol’s brightness returns to normal after another five hours. Predictions of Algol’s eclipses can be found in astronomical annuals and magazines. Rho (ρ) Persei is a variable of a different kind: it is a red giant that fluctuates by about 50 percent in brightness every seven weeks or so. Popularly termed the Double Cluster, the twin open clusters NGC 869 and NGC 884 are one of the showpieces of the northern sky. Each cluster contains hundreds of stars of 7th magnitude and fainter, and covers an area of sky similar to that of a full moon. They lie more than 7,000 light-years away in the Perseus spiral arm of our galaxy. Both clusters are noticeable to the naked eye as a brighter patch in the Milky Way near the border with Cassiopeia and can be seen well through binoculars or a small telescope. M34 is a scattered open cluster of several dozen stars near the border with Andromeda. It covers an apparent area similar to that of a full moon and is easy to spot through binoculars.

THE VICTORIOUS HERO

Perseus 24

SIZE RANKING

BRIGHTEST STAR

Mirphak (α) 1.8 GENITIVE

Persei

ABBREVIATION

Per

HIGHEST IN SKY AT 10 PM

November–December FULLY VISIBLE

90°N–31°S

Perseus is a prominent northern constellation lying in the Milky Way between Cassiopeia and Auriga. It is an original Greek constellation and represents Perseus, who was sent to slay Medusa, the Gorgon. In the sky, Perseus is depicted with his left hand holding the Gorgon’s head, which is marked by Algol—Beta (β) Persei—a famous variable star (see p.276). His right hand brandishes his sword, marked by the twin clusters NGC 869 and NGC 884. SPECIFIC FEATURES The constellation’s brightest member—Mirphak, or Alpha (α) Persei—is of magnitude 1.8. It lies at the center of a group of stars known as the Alpha Persei Cluster or Melotte 20. Scattered over an area of sky that is several times the diameter of a full moon, the cluster is an excellent sight through binoculars. Algol is an eclipsing binary consisting of two stars in close orbit, one much hotter and brighter than the other. Together they shine at magnitude 2.1, but every 69 hours the fainter star eclipses its companion. Over a period of five hours, the combined light

MYTHS AND STORIES

MEDUSA Perseus, the son of Zeus and Danaë, was sent to bring back the head of Medusa, the Gorgon, whose evil gaze turned everything to stone. He was given a bronze shield by the goddess Athene, a sword of diamond by Hephaestus, and winged sandals by Hermes. Looking only at Medusa’s reflection in his shield, Perseus managed to decapitate the Gorgon. SUCCESSFUL MISSION

Perseus proudly displays the severed head of Medusa, the Gorgon, in this neoclassical sculpture by Antonio Canova.

ALPHA PERSEI CLUSTER 2

Mirphak and its surrounding cluster lie above center. The Pleiades Cluster is lower right, and Capella, in Auriga, is lower left.

THE VICTORIOUS HERO

5h 4h

2h

3h

CASSIOPEIA

CAMELOPARDALIS

η

NGC 869 NGC 884

4

γ λ

NGC 1528

AURIGA

μ

Capella

MELOTTE 20 34

δ

ψ σ

48

53

M76

τ Mirphak

α ι

TH E NI G H T S KY

32

ν ε

52

Per A

PERSEUS 54

TAURUS

NGC 1499

ζ

40

ο

40

Algol

NGC 1342

ξ

ANDROMEDA M34

β ωρ

˚

θ

κ 58

50

ϕ

π 16

˚

12

TRIANGULUM

24 17 30

ARIES

˚ DOUBLE CLUSTER 15

Of these two star clusters, NGC 869 (left) appears to be more densely packed. NGC 884 (right) contains some red giant stars, which its neighbor lacks.

THE CONSTELLATIONS

371

THE RAM

Aries SIZE RANKING

39

BRIGHTEST STAR

Hamal (α) 2.0 GENITIVE

Arietis

ABBREVIATION

Ari

HIGHEST IN SKY AT 10 PM

November–December FULLY VISIBLE

90°N–58°S

This not particularly conspicuous constellation of the zodiac is found between Pisces and Taurus. Its most recognizable features are three stars near the border with Pisces: Alpha (α), Beta (β), and Gamma (γ) Arietis, of 2nd, 3rd, and 4th magnitudes. Aries depicts the golden-fleeced ram of Greek legend (see panel, below). Over 2,000 years ago, the vernal equinox—the point at which the ecliptic crosses the celestial equator—lay near the border of Aries and Pisces. The effect of precession (see p.64) has now moved the vernal equinox almost into Aquarius, but it is still called the first point of Aries. SPECIFIC FEATURES Gamma was one of the first stars discovered to be double, and it was found by the English scientist Robert Hooke in 1664, when telescopes were still quite crude and it was not realized that double stars are numerous. To the naked eye, it appears of 4th magnitude, but when viewed through a small telescope it consists of nearly identical white stars of magnitudes 4.6 and 4.7. Lambda (λ) Arietis, of 5th magnitude, has a companion of 7th magnitude that can be seen through large binoculars. Pi (π) Arietis, also of 5th magnitude, has a very close companion of 8th magnitude.

EASY DOUBLE 5

Gamma (γ) Arietis is readily separable by a small telescope to reveal a pair of white stars, each of 5th magnitude.

THE RAM 4h

2h

3h

PERSEUS

TRIANGULUM 30

39 41

˚

35 14 Hamal

ζ

ε

α

ARIES

λ

β γ Mesartim

20

Sheratan

δ

˚

π TAURUS

ECL

IPTI

C 10

˚

CETUS PISCES

MYTHS AND STORIES

THE GOLDEN FLEECE

LEGENDARY RAM 2 GOLDEN MOMENT

Watched by an admiring Medea, Jason removes the glittering fleece from the oak tree on which it hung at Colchis, in this illustration by L. du Bois-Reymond.

From a crooked line formed by three faint stars, ancient astronomers visualized the figure of a crouching ram, with its head turned back over its shoulder.

TH E NI G H T S KY

Aries represents the ram whose golden fleece hung on a tree in Colchis on the Black Sea. Jason and the Argonauts undertook an epic voyage to bring this fleece back to Greece. Jason was aided in his task by Medea, who had fallen in love with him. She was the daughter of King Aeetes, who owned the fleece. Medea bewitched the serpent guarding the fleece so that Jason could steal it. Taking Medea and the fleece with him, Jason then sailed away in the Argo.

372

THE CONSTELLATIONS THE BULL

Taurus SIZE RANKING

17

BRIGHTEST STAR

Aldebaran (α) 0.85 GENITIVE

Tauri

ABBREVIATION

Tau

HIGHEST IN SKY AT 10 PM

December–January FULLY VISIBLE

88°N–58°S

Taurus is a large and prominent northern constellation of the zodiac, and it contains a wealth of objects including the Pleiades and Hyades star clusters (see p.291 and p.290) and M1, the Crab Nebula (see pp.270–71). Its stars represent the head and forequarters of a mythical Greek bull. The Hyades cluster is centered on the bull’s face, while the constellation’s brightest star, Aldebaran—Alpha (α) Tauri (see p.256)—is its glinting eye. Alnath (or Elnath)—Beta (β) Tauri—and Zeta (ζ) Tauri mark the tips of the bull’s long horns. Each November, the Taurid meteors appear to radiate from a point south of the Pleiades. SPECIFIC FEATURES Aldebaran is a red giant whose color is clearly apparent to the naked eye. As with many red giants, it is slightly variable in brightness, but the amount is only about one-tenth of a THE CRAB NEBULA 54

This supernova reveals the beauty of a massive star’s violent death throes. Convoluted filaments of gas expand away from the site of the supernova explosion, which was seen from Earth in AD 1054.

magnitude either side of its average HYADES AND PLEIADES 21 value of 0.85 and is barely noticeable. The Hyades (lower left) is the Although Aldebaran appears to be larger of these two dazzling star part of the Hyades cluster, it is clusters; the Pleiades (upper 67 light-years away—less than half right) is a tighter bunch that appears hazy at first glance— the cluster’s distance—and is good viewing conditions are superimposed only by chance. needed to see all nine named The main stars of the Hyades are stars with the naked eye. arranged in a V-shape that is the width of over ten diameters of a full supernova remnant resembled the legs an unrelated cloud into which the moon. More than a dozen stars are of a crab. The Crab Nebula is found cluster has drifted. visible with the unaided eye, and two diameters of a full moon away The first object on Charles dozens more come into view through from Zeta Tauri. Through a small Messier’s list of cometlike objects binoculars. At 150 light-years away, telescope, it appears as a faint (see p.73), M1 is the remains of a the Hyades is the closest major star elliptical glow several times larger star that exploded as a supernova in cluster to Earth. On one arm of the AD 1054. It was given its popular than the disk of Jupiter. Large Hyades’ V-shape is a wide double name. the Crab Nebula, by the Irish apertures are needed to make out star, Theta (θ) Tauri. At magnitude astronomer William Parsons (see the level of detail seen by Parsons. 3.4, the brighter of the pair, Theta-1 p.315) in 1844, because he thought (θ1), is also the brightest member of the Hyades. Another double star that the filaments of gas that is easy to spot is Sigma (σ) Tauri, protruded from the 4h 5h which has two 5th-magnitude components, near Aldebaran. The 6h PERSEUS apex of the Hyades cluster points 30 toward Lambda (λ) Tauri, an ˚ eclipsing binary of the same type as Algol (in Perseus). It varies between ϕ 136 βAlnath magnitudes 3.4 and 3.9 in a cycle PLEIADES GEMINI TAURUS 139 lasting just under four days. M45 132 An even brighter star cluster is τ NGC 1746 υ 37 ARIES the Pleiades, which hovers over the M1 κ ι 20 114 109 bull’s shoulders. Although popularly ζ ˚ NGC 1647 ω known as the Seven Sisters, after a 119 ECLIP T ε TIC group of mythical Greek nymphs 126 α (see panel, opposite), the Pleiades HYADES Aldebaran in fact contains nine named stars: 5 the seven sisters and their parents, 134 Atlas and Pleione. The brightest 90 λ ORION 10 member is Alcyone (see p.277), ξ ˚ which is of magnitude 2.9 and lies 88 μ 47 ο CETUS near the center of the cluster. The Betelgeuse ν Pleiades covers an area of sky three times the width of a full moon. On long-exposure photographs of the Pleiades, a surrounding haze is 10 0 visible. This was once thought to ˚ THE BULL be leftover gas and dust from the stars’ ERIDANUS formation, but it is now recognized as

THE PLEIADES 25

24

˚

3h 50m Maia Alcyone Pleione Atlas

˚

d

TH E NI G HT S KY

18

¡

0.0–0.9

b

˚

_

89 

75

2.0–2.9

63

e 70

85  81 80 e

l

1.0–1.9

b

b

17 Aldebaran

m

Merope

4h 30m

˚

m

Asterope Taygeta Celaeno Electra

MAGNITUDE KEY

THE HYADES 4h 40m

3h 45m

a

4.0–4.9

71 58

76

/

60

3.0–3.9

57

5.0–5.9 6.0–6.9

373

MYTHS AND STORIES

THE LOST PLEIAD

Taurus, the celestial bull, thrusts his startipped horns into the night air. The bull is said to represent a disguise adopted by Zeus in a Greek myth. The bright reddish “star” seen here on the bull’s back, below the Pleiades, is actually the planet Mars.

TH E N I G HT S KY

RAGING BULL 2

The popular name for the Pleiades is the Seven Sisters, although only six stars are easily visible to the naked eye. Two myths have arisen to explain the “missing” Pleiad. One myth says that the star that shines least brightly is Merope, the only one of the seven sisters to marry a mortal. Another story says that it is Electra, who could not bear to stay and watch the fall of Troy, the city founded by her brother. The names of the stars in the WANDERING STAR cluster do not follow either This 19th-century painting, of these legends, however, for The Lost Pleiad, depicts the separation of one of the the faintest named member Pleiades from her sisters. is actually Asterope.

374

THE CONSTELLATIONS mark the heads of the twins, while their feet lie bathed in the Milky Way. In mid-December each year, the Geminid meteors radiate from a point in Gemini near Castor.

THE TWINS

Gemini SIZE RANKING

30

THE ESKIMO NEBULA 54

The planetary nebula NGC 2392 is so called because it is surrounded by a fringe of gas that resembles the furlined hood of an Inuit parka.

BRIGHTEST STAR

SPECIFIC FEATURES Castor is a remarkable multiple star. To the naked eye, it appears as a single entity of magnitude 1.6, but through a small telescope with suitably high magnification, it divides into a sparkling blue-white duo of 2nd and 3rd magnitudes. The two stars form a genuine binary, with an orbital period of 450 years, which also has a 9th-magnitude red dwarf companion. Although these three stars cannot be divided further visually, each is a spectroscopic binary, bringing the total number of stars in the Castor system to six.

Pollux (β) 1.2 GENITIVE

Geminorum

ABBREVIATION

Gem

HIGHEST IN SKY AT 10 PM

January–February FULLY VISIBLE

90°N–55°S

This prominent zodiacal constellation represents the mythical twins Castor and Pollux, who were the sons of Queen Leda of Sparta and the brothers of Helen of Troy (see Leda and the Swan, p.367). The constellation is easily identifiable within the northern sky because of its two brightest stars, which are named after the twins. Even though it is labeled Beta (β) Geminorum, Pollux is brighter than Castor, or Alpha (α) Geminorum (see p.276). The two stars

8h

THE TWINS

6h

7h

AURIGA

ο 30

˚

Castor

χ ϕ

β

σ Pollux

υ κ

ε

GEMINI

δ

ECLIPT

˚

τ

μ

ζ

λ

η

Nebula, or NGC 2392 (see p.259), a planetary nebula with a bluish disk similar in size to that of the globe of Saturn and visible through a small telescope. Larger telescope apertures are needed to reveal the nebula’s surrounding fringe of gas, reminiscent of an Inuit parka, that gives NGC 2392 its popular name. An alternative name for this nebula is the ClownFace Nebula.

1

ν Alhena

38 10

The large star cluster M35 is visible through binoculars; larger telescopes reveal a fainter and more distant cluster, NGC 2158 (bottom right), in the same field of view.

M35

NGC 2392

81

LARGE AND SMALL CLUSTER 15

ι

IC

20

θ

αρ

Although Castor and Pollux are named after twins, the stars themselves are far from identical. Being an orange giant, Pollux is noticeably warmer-toned than Castor. It is also closer to Earth, lying only 34 light-years away, compared to Castor’s 51 light-years. The open star cluster M35 lies at the feet of the twins. Under clear skies, this cluster can be glimpsed with the naked eye, but it is more easily found with binoculars, through which it appears as an elongated, elliptical patch of starlight spanning the same apparent width as a full moon. When viewed through a small telescope, its individual stars seem to form chains or curved lines. Two variable stars of note in Gemini are Zeta (ζ) Geminorum (see p.286), which is a Cepheid variable that ranges between magnitudes 3.6 and 4.2 every 10.2 days, and Eta (η) Geminorum (see p.284), which is a red giant whose brightness can vary anywhere between magnitudes 3.1 and 3.9. This constellation also contains the Eskimo

ξ

ORION

γ

TAURUS

30

˚ CANCER Procyon

CANIS MINOR

Betelgeuse

TH E N I G H T S KY

MONOCEROS

CELESTIAL TWINS 2

Castor and Pollux, the twins of the Greek myth, stand side by side in the sky between Taurus and Cancer. The bright “star” in the middle of Gemini in this picture is actually the planet Saturn.

THE CONSTELLATIONS is Zeta (ζ) Cancri. Its components, of 5th and 6th magnitude, form a binary star with an orbital period of more than 1,000 years. The Beehive Cluster (M44) is a large open cluster at the the heart of Cancer, located between Gamma (γ) and Delta (δ) Cancri. The ancient Greeks could see the cluster as a misty spot with the unaided eye, but in modern urban skies it is unlikely to be visible without binoculars. This cluster consists of a scattering of stars of 6th magnitude and fainter. It appears to cover an area more than three times wider than the diameter of a full moon, and although it can be seen through binoculars, it is too wide to fit in the field of view of most telescopes. The Beehive Cluster’s glory overshadows another open cluster, M67, which is smaller and denser yet

THE CRAB

Cancer SIZE RANKING

31

BRIGHTEST STAR

Beta (β) 3.5 GENITIVE

Cancri

ABBREVIATION

Cnc

HIGHEST IN SKY AT 10 PM

February–March FULLY VISIBLE

90°N–57°S

Cancer is the faintest of the 12 zodiacal constellations, lying in the northern sky between Gemini and Leo, and it represents the crab of Greek mythology (see panel, right). Cancer includes the major open star cluster M44 (see p.290), which is alternatively known as the Beehive Cluster, the Manger Cluster, or Praesepe—which is the Latin for both “hive” and “manger.” It also includes the stars Gamma (γ) and Delta (δ) Cancri, which represent two donkeys feeding at the manger. These two stars are sometimes known as Asellus Borealis and Asellus Australis, the northern and southern asses. SPECIFIC FEATURES Iota (ι) Cancri is a 4th-magnitude yellow giant with a nicely contrasting 7th-magnitude blue-white companion. The companion is just detectable through 10 x 50 binoculars, and it is easy to identify through a small telescope. Another double star that can be seen through a small telescope

still the width of a full moon in the sky. It lies about 2,600 light-years away—more distant than the Beehive Cluster, which is 520 light-years away. M67 can be found with binoculars, but a telescope is needed to resolve individual stars. At an estimated age of around 5 billion years, it is one of the oldest open clusters known—it is also of an age similar to Earth’s.

375

MYTHS AND STORIES

A SMALL VICTORY According to the Greek story, a crab attacked Hercules during his fight with the many-headed Hydra but was crushed underfoot during the struggle. Such a minor role befits this faint constellation. SCUTTLING AWAY

THE BEEHIVE CLUSTER 1

Also known as the Manger Cluster, M44 is an open cluster located between the two asses feeding from the manger, Gamma (γ) (center, top) and Delta (δ) Cancri (center, bottom).

A small crab can be seen in the foreground of this 18th-century engraving, Hercules Fights the Lernean Hydra.

M67 15

Inferior to M44, but still worthy of note, M67 can be found with binoculars in the region of Cancer south of the ecliptic.

THE CRAB

8h

9h

LYNX Castor

ι

Pollux

GEMINI 20

γ

˚ ECLI

PTIC

CANCER M44

δ

ζ

10

LEO

˚

α

M67

β

CANIS MINOR Procyon

0

˚

SEXTANS

HYDRA MONOCEROS

HIDDEN CRAB 2

Cancer is the faintest constellation in the zodiac, but it contains a major star cluster, M44, which is just visible in this photograph as a hazy patch near the center of the constellation.

T HE N I G H T S K Y

Regulus

376

THE CONSTELLATIONS

11h

SPECIFIC FEATURES Unusually, this constellation has no star labeled Alpha. This is due to an error by the 19th-century English astronomer Francis Baily, who assigned the Greek letters to the constellation’s stars. When doing so, he overlooked assigning a Bayer letter to the brightest star, 46 Leonis Minoris, which should have been recorded as Alpha (α), although he did label the second-brightest star as Beta (β) Leonis Minoris. Although Leo Minor contains no objects of interest for users of binoculars or a small telescope, Beta (β) is a close double star that can be separated by a telescope with very large aperture. It has a magnitude of 4.2, and its component stars orbit each other every 37 years.

THE LITTLE LION

Leo Minor SIZE RANKING

64

BRIGHTEST STAR

46 Leonis Minoris 3.8 GENITIVE

Leonis Minoris ABBREVIATION

LMi

HIGHEST IN SKY AT 10 PM

March–April FULLY VISIBLE

90°N–48°S

This small, insignificant constellation, adjacent to Leo in the northern sky, represents a lion cub, although this is not suggested by the pattern of its stars. It was introduced in the 17th century by the Polish astronomer Johannes Hevelius (see p.384).

LYNX

˚ β

10 21

30

46 37 30

˚

LEO MINOR

LEO

20

˚

THE LITTLE LION

Having located the distinctive shape of the Sickle in Leo (top, right), look north of it to find the faint stars of Leo Minor.

SPECIFIC FEATURES The Coma Star Cluster, also known as Melotte 111, is the constellation’s main feature. It comprises several dozen faint stars, which fan out distinctively for several diameters of a full moon southward from Gamma (γ) Comae Berenices. This open cluster, which is seen to best advantage through binoculars, has been imagined as both the bushy tip of a lion’s tail and a lock of Berenice’s hair. Coma Berenices contains numerous galaxies in its southern half. Most of these are members of the Virgo Cluster, such as M85, M88, M99, and M100, but two notable exceptions, M64 (see p.314) and NGC 4565, are closer to the Earth. Popularly known as the Black Eye Galaxy, M64 is a spiral galaxy tilted at an angle to the Earth, which is seen as

Coma Berenices 42

BRIGHTEST STAR

Beta (β) 4.2 GENITIVE

Comae Berenices ABBREVIATION

40

THE LION CUB 2

BERENICE’S HAIR

SIZE RANKING

10h

URSA MAJOR

Com

HIGHEST IN SKY AT 10 PM

April–May FULLY VISIBLE

90°N–56°S

Coma Berenices represents the flowing locks of Queen Berenice of Egypt, which she cut off as a tribute to the gods after the safe return of her husband, Ptolemy III, from battle during the 3rd century BC. It is a faint but interesting northern constellation, lying between Leo and Boötes. In the mid-16th century, it was named as a constellation by the Dutch cartographer Gerardus Mercator. Before then, its stars were regarded as forming the tail of Leo.

an elliptical patch of light through a small telescope; it is best seen with a telescope with an aperture of 6 in (150 mm) or more. A dust cloud near the galaxy’s nucleus creates the “black eye” effect. NGC 4565, another spiral galaxy, lies edge-on to the Earth and is more difficult to spot. It appears long and thin when viewed through a telescope with a 4-in (100-mm) aperture, and a lane of dark dust is revealed in long-exposure photographs.

NGC 4565 54

Seen edge-on, this spiral galaxy displays a lane of dark dust along its spiral arms when viewed through larger apertures.

THE BLACK EYE GALAXY 54

The spiral galaxy M64 sports a large, dark dust cloud near its core, giving it the appearance of a blackened eye.

BERENICE’S HAIR

12h

13h

14h 30

37

β

γ

TH E NI G HT S KY

41

31

FS M64

BOOTES Arcturus

˚

MELOTTE 16 14 111 NGC 4565 12 7 23 20

35 M53

α COMA BERENICES

˚

LEO M85

36 M91

M88

MANE OF HAIR 2

11 M100 M98 M99

10

VIRGO

˚

The distinctive splay of the Coma Star Cluster marks out Coma Berenices in the night sky. Leo’s hindquarters can be seen closer to the horizon.

THE LION

Leo SIZE RANKING

12

BRIGHTEST STAR

Regulus (α) 1.4 GENITIVE

Leonis

ABBREVIATION

Leo

HIGHEST IN SKY AT 10 PM

March–April FULLY VISIBLE

82°N–57°S

The outline stars of Leo really do bear a marked resemblance to a crouching lion, in this large constellation of the zodiac, located just north of the celestial equator. It is one of the easiest constellations to recognize. The pattern of six stars that marks the lion’s head and chest is known as the Sickle and is shaped like a reversed question mark or a hook. The Leonid meteors radiate from the region of the Sickle every November (see pp.220–21).

SPECIFIC FEATURES Regulus—Alpha (α) Leonis (see p.253)—lies at the foot of 30 ˚ the Sickle. It is the faintest of the first-magnitude stars, at magnitude 1.4, and its wide companion is of 8th magnitude. The double star Algieba, or Gamma (γ) Leonis, consists of components of magnitudes 2.2 20 ˚ and 3.5. Both stars are orange giants, and they orbit each other every 600 years or so. A nearby star—40 Leonis—is unrelated. Zeta (ζ) Leonis is a wide triple star, consisting of a 3rd-magnitude star with a 10 6th-magnitude companion to ˚ both the north and south, which can be seen with binoculars. All three stars are at different distances from Earth and, hence, they are unrelated. A pair of spiral galaxies, M65 0 and M66, can be glimpsed with a ˚ small telescope beneath the hind quarters of Leo. A fainter pair of spirals, M95 and M96, lie under the lion’s body, as does an elliptical galaxy, M105, about one degree away. -10

377

10h

11h

LYNX

13h

URSA MAJOR

LEO MINOR

κ

μ

δ

93

ζ

54

72 60

Algieba

ε γ

THE SICKLE

40

θ

β Denebola

M105

ι

M95

ρ

χ

Regulus

R 31

π

ξ

ο 10

HYDRA SEXTANS

NGC 3521

˚

α

58

υ 87

ECL

59

τ VIRGO

IC

IPT

M96

σ

NGC 2903

η

LEO

NGC 3628

M65 M66

λ

ϕ

61

CRATER

THE LION

LEO TRIPLET 54

ALGIEBA 5

This beautiful pair of golden-colored orange giants is clearly visible through small telescopes.

A trio of galaxies lies near Theta (θ) Leonis: M65 (lower right); M66 (lower left); and the edge-on spiral NGC 3628 (top). Although NGC 3628 appears the largest on photographs, it is less bright than the others and is difficult to see through small telescopes.

MYTHS AND STORIES

HERCULES AND THE LION THE BIG CAT 2

Leo represents the mythical lion that lived in a cave near the Greek town of Nemea, terrorizing the area and emerging to attack and devour local inhabitants. As the first of the 12 labors in his quest for immortality, Hercules was sent by his cousin Eurystheus to kill the lion. Finding that the creature’s hide was impervious to his arrows, Hercules instead wrestled and strangled the beast. He then used the lion’s own razor-sharp claws to cut off its pelt, which he wore victoriously as a cloak. THE HERO AND THE BEAST

Hercules grapples with the Nemean Lion in a sculpture by the 16th-century Flemish artist Jean de Boulogne, or Giambologna.

T HE N I G H T S KY

The crouching lion is a distinctive sight in the night sky. The pattern of its stars is disturbed here by the presence of Jupiter under the lion’s body.

378

THE CONSTELLATIONS THE VIRGIN

Virgo SIZE RANKING

2

BRIGHTEST STAR

Spica (α) 1.0 GENITIVE

Virginis

ABBREVIATION

Vir

HIGHEST IN SKY AT 10 PM

April–June FULLY VISIBLE

67°N–75°S

Virgo straddles the celestial equator, between Leo and Libra. It is the largest constellation of the zodiac, and the second-largest overall. The constellation depicts a Greek virgin goddess (see panel, right). Virgo contains the Virgo Cluster (see p.329), the closest large cluster of galaxies to Earth, which is some 50 million light-years away and which extends over the border of Virgo into Coma Berenices. The Sun is in Virgo during the September equinox each year. SPECIFIC FEATURES Gamma (γ) Virginis, or Porrima (see p.253), is a binary star with the relatively short period of 169 years. As a result of this short period, the effects of the two stars’ orbital motions can easily be followed through amateur telescopes. As seen from Earth, the two stars were closest together in 2005, when a telescope with an aperture of 10 in (250 mm) was needed to separate them. By 2012, the stars had moved far enough apart that they could be divided by a telescope

of only 2.4 in (60 mm). For the MYTHS AND STORIES rest of the 21st century, it will be possible to split the components of THE VIRGIN GODDESS Gamma Virginis with a small-aperture telescope. Both of the stars are of Virgo is usually identified as Dike, magnitude 3.5. the Greek goddess of justice, who In the upper part of Virgo’s body abandoned the Earth and flew up lie the numerous galaxies of the to heaven when human behavior Virgo Cluster. None is easy to see deteriorated. Neighboring Libra with a small instrument. The brightest represents her scales of justice. Virgo members are giant ellipticals, notably is also visualized as Demeter, the M49, M60 (see p.317), M84, M86, harvest goddess, who holds an ear of and M87 (see p.323). M87 is a strong wheat, which is represented by the radio and X-ray source also known as constellation’s brightest star, Spica. Virgo A. Long-exposure photographs show it is ejecting a jet of gas, like BOUNTIFUL OFFERINGS certain quasars. Demeter presented Triptolemus, a prince of Eleusis, The Sombrero Galaxy (see p.316), with a chariot drawn by winged dragons and grains of wheat to sow crops wherever he traveled. or M104, is Virgo’s best-known galaxy. This spiral is about two-thirds as far away as the Virgo Cluster. It is 12h oriented almost edge-on to the Earth, Arcturus 14h 13h so that a dark lane of dust in the COMA galaxy’s plane crosses its central bulge. BERENICES The bulge may be all that can be seen BOOTES M86 M90 LEO through a small telescope; the dust 70 M84 M89 lane is only revealed M87 M58 ε 10 when seen through M60 M59 ˚ ρ ο a large-aperture ξ M49 telescope or on longν exposure photographs. π σ The brightest quasar M61 δ 78 in the sky, 3C 273 110 16 109 β (see p.325), also lies 3C 273 in the bowl of Virgo. τ 0 ˚ However, it is much Porrima η ζ ϕ more distant than the VIRGO γ Virgo Cluster. Through most telescopes, it μ θ ι appears as nothing more 74 χ than a 13th-magnitude star. LIBRA ψ Only professional equipment -10 ˚ M104 will reveal it as the center κ α Spica of an active galaxy, which is some 2,000 million lightIC IPT λ years away from Earth. ECL 69 CRATER CORVUS

61

89

THE WHEAT GODDESS 2

Spica (bottom, left), is one of the 20 brightest stars in the sky. Its name is Latin for “ear of wheat,” and it marks the bounty that the Virgin holds in her left hand.

THE SOMBRERO GALAXY 5

The Sombrero Galaxy (M104) is a spiral galaxy with a large central bulge, seen almost edge-on, and resembling a Mexican hat. It lies about 30 million light-years away.

TH E NI G H T S KY

M87 54

Through a small telescope, the giant elliptical galaxy M87 appears as a rounded glow, but photographs and CCD images reveal the jet of gas that is being expelled from its highly active nucleus. Here, the jet is just visible near the top right of the core.

-20

˚

THE VIRGIN

HYDRA

THE CONSTELLATIONS Zubeneschamali (“the northern claw”) or Beta (β) Librae, which shows a greenish tinge when viewed through binoculars or a telescope. This highly unusual coloring is due, presumably, to the chemical composition of Zubeneschamali’s outer layers. In the heart of the constellation lies Iota (ι) Librae, a double with stars of 5th and 6th magnitudes which can be viewed through binoculars. A small telescope will reveal the closer 9th-magnitude companion of

THE SCALES

Libra SIZE RANKING

29

BRIGHTEST STAR

Beta (β) 2.0 GENITIVE

Librae

ABBREVIATION

Lib

HIGHEST IN SKY AT 10 PM

May–June FULLY VISIBLE

60°N–90°S

the brighter star. Mu (μ) Librae, with components of 6th and 7th magnitude, is a more difficult pair to separate; a telescope with 3 in (75 mm) aperture is needed.

Delta (δ) Librae is an eclipsing variable. Every two days eight hours, it rises and falls between 5th and 6th magnitudes. This change can be easily followed with binoculars.

THE SCALES

15h

SERPENS CAPUT

11

VIRGO 16

LIBRA Zubeneschamali -10

˚

37

OPHIUCHUS

This constellation of the zodiac lies just south of the celestial equator between Virgo and Scorpius. Originally, the ancient Greeks visualized the constellation as the claws of the neighboring Scorpius, which is why Libra’s brightest stars have names that mean “northern claw” and “southern claw.” Libra’s present-day identification as Virgo’s scales of justice became more common in Roman times.

θ -20

ι

NGC 5897

Antares

˚

σ

υ τ

SCORPIUS LIBRA’S STARS 2

Now regarded as the scales of justice, the stars of Libra were once visualized as the claws of the adjacent scorpion, Scorpius.

Corona Borealis has three double stars of note for small-instrument users, although none is particularly bright. Nu (ν) Coronae Borealis is a pair of 5th-magnitude red giants divisible with binoculars. Zeta (ζ) Coronae Borealis is a blue-white pair, with

Corona Borealis 73

BRIGHTEST STAR

Alphekka or Gemma (α) 2.2

components of 5th and 6th magnitudes—an attractive sight when seen through a small telescope—while Sigma (σ) Coronae Borealis is a yellow pair with components of 6th and 7th magnitudes, which can also be split with a small telescope.

GENITIVE

Coronae Borealis CrB

HIGHEST IN SKY AT 10PM

June FULLY VISIBLE

90˚N–50˚S THE NORTHERN CROWN

MYTHS AND STORIES

PRINCESS ARIADNE Ariadne, daughter of King Minos of Crete, helped Theseus slay the Minotaur, a gruesome creature that was half bull, half human. Theseus sailed off with Ariadne to the island of Naxos, where he then abandoned her. The god Dionysus looked down on the princess and was overcome. At their wedding, Ariadne wore a jewel-studded crown, which Dionysus threw into the sky, where the crown’s jewels were changed into stars. CROWNING GLORY

Dionysus, known as Bacchus by the Romans, holds Ariadne’s jeweled crown in this painting by the 17th-century French artist Eustache Le Sueur.

16h

BOOTES 40

˚ τ

κ

ν σ

ζ

CORONA

30

˚

ξ BOREALIS θ ι R β ε γ α T

Alphekka

δ HERCULES

CROWN OF STARS 2

Like a celestial tiara, the seven main stars of Corona Borealis form a distinctive arc between Boötes and Hercules.

T HE N I G H T S KY

SPECIFIC FEATURES The arc of the northern crown contains the remarkable variable star R Coronae Borealis (see p.287), a yellow supergiant normally of 6th magnitude, which shows sudden dips in brightness. These fades, which are due to a build-up of sooty particles in its atmosphere, occur every few years and can last for months.

Zubenelgenubi

TIC

ECLIP

42

THE NORTHERN CROWN

Corona Borealis is a small but distinctive constellation in the northern sky, between Boötes and Hercules, consisting of a horseshoe shape of seven stars. It is one of the original Greek constellations and represents the crown worn by Princess Ariadne (see panel, right).

β δ μ α1,2

κ

˚

-30

ABBREVIATION

ε

γ

48

SPECIFIC FEATURES Zubenelgenubi (Arabic for “the southern claw”) or Alpha (α) Librae is a wide double star of 3rd and 5th magnitudes and is easily divisible with binoculars or even sharp unaided eyesight. To the north of this pair is the constellation’s brightest star,

SIZE RANKING

379

380

THE CONSTELLATIONS THE SERPENT

Serpens SIZE RANKING

23

BRIGHTEST STAR

Unukalhai (α) 2.6 GENITIVE

Serpentis ABBREVIATION

Ser

HIGHEST IN SKY AT 10 PM

June–August

Delta (δ) Serpentis, near the serpent’s head, is a binary with components of 4th and 5th magnitudes. It is divisible using high powers of magnification on a small telescope. Theta (θ) Serpentis, near the serpent’s tail, is a pair of white stars that are easily split through a small telescope. This wide double star has components of magnitude 4.6 and 5.0.

about twice the size of M16. It is situated in Serpens Cauda near the tip of the serpent’s tail. Close to the border with Virgo lies M5, which is about 25,000 light-years away. Its condensed center appears as a faint area about half the size of a full moon, when viewed with binoculars, while the curving chains of stars in its outskirts are revealed only through a telescope with an aperture of 4 in (100 mm) or more.

30

˚

16h

CORONA BOREALIS

20

γ

19h

Although counted as a single constellation, Serpens is in fact split into two separate areas, and is thus unique. It is one of the original 48 Greek constellations and straddles the celestial equator. Serpens represents a huge snake coiled around Ophiuchus, who holds the head (Serpens Caput) in his left hand and the tail (Serpens Cauda) in his right. In Greek mythology, snakes were a symbol of rebirth, because of the fact that they shed their skins. Ophiuchus represents the great healer Asclepius, who was reputedly able to revive the dead (see panel, opposite).

TH E NI G HT S KY

SPECIFIC FEATURES The Eagle Nebula (see pp.244–45) in Serpens Cauda was made worldfamous by a spectacular Hubble Space Telescope picture of dark columns of dust embedded within its glowing gas. Unfortunately, the dust columns show up only through a telescope of large aperture and on long-exposure photographs such as those from the Hubble Space Telescope. The Eagle Nebula contains a star cluster, M16, which can be spotted readily through binoculars or a small telescope. It appears as a hazy patch covering an area of sky that is similar in size to a full moon. Another open cluster that is visible through binoculars is IC 4756, which appears

18h

˚

β

R

74°N–64°S 10

ρ κ ι

˚

THE SERPENT

FULLY VISIBLE

SERPENS CAPUT

π

17h

δ λ

θ 0

ε

IC 4756

OPHIUCHUS

Unukalhai

α

M5

σ

˚ η

–10

ζ

˚ M16 SERPENS

SCUTUM

–20

CAUDA

μ

ν

ο ξ

˚

M5 15

This is one of the finest globular clusters in northern skies. M5 is noticeably elliptical in shape when viewed through a telescope.

SERPENTINE STARS 2 THE EAGLE NEBULA 543

This image was captured by a professional four-meter telescope. It can only be seen well with telescopes of large aperture.

The upper part of the snake (above, right) contains Unukalhai (α), which derives its name from the Arabic for “the serpent’s neck.”

18h

381

17h

HERCULES THE SERPENT HOLDER

Ophiuchus SIZE RANKING

11

BRIGHTEST STAR

Rasalhague (α) 2.1 GENITIVE

Ophiuchi ABBREVIATION

Oph

HIGHEST IN SKY AT 10 PM

June–July FULLY VISIBLE

59°N–75°S

This large constellation straddling the celestial equator depicts a man holding a snake. The head of Ophiuchus adjoins Hercules in the north, while his feet rest on Scorpius in the south. The Sun passes through Ophiuchus in the first half of December, but despite this the constellation is not regarded as a true member of the zodiac. Ophiuchus was the site of the last supernova explosion seen in our galaxy, which appeared in 1604. It far outshone all other stars and is known as Kepler’s Star (see p.273) after Johannes Kepler, who wrote about it in De stella nova (see p.68). SPECIFIC FEATURES Lying on the edge of the Milky Way, in the direction of the center of our galaxy, Ophiuchus contains numerous star clusters. Messier cataloged seven

globular clusters, although none is particularly prominent. M10 and M12 (see p.295) are both near the center of the constellation and detectable through binoculars on a clear night. Better sights for binoculars are two large and scattered open clusters, NGC 6633 and IC 4665. An outstanding multiple star is Rho (ρ) Ophiuchi, lying near Antares (in neighboring Scorpius). This 5thmagnitude star has a 7th-magnitude companion either side of it, and these are best viewed through binoculars. Another 6th-magnitude companion that is much closer to the central star can be identified through a small telescope using high magnification. The complex nebulosity in this area, including around Antares, is revealed only in long-exposure photographs. The beautiful double star 70 Ophiuchi consists of yellow and orange dwarfs, with components of 4th and 6th magnitudes, while the double star 36 Ophiuchi is a pair of orange dwarfs with components of 5th magnitude. Barnard’s Star is the most celebrated star in Ophiuchus and is the second-closest star to the Sun. Even though this red dwarf is a mere 5.9 light-years away, its light output is so feeble that it appears as only magnitude 9.5, and it is too faint to see without a telescope. Barnard’s Star is moving so quickly relative to the background stars that its change in position is noticeable over a matter of only a few years (see chart, right).

α

Rasalhague 10

˚

ι

72

κ

71 IC 4665

NGC 6633 NGC 6572

74 0

OPHIUCHUS

β

66

γ

67 70 68

˚

σ λ 41 M12

M14

–10

RS

˚

ε

M10

30

SCUTUM

μ

υ

ν

ζ

20 M107

SERPENS CAUDA –20

η

ϕ

χ

M9

˚

ξ

58

51 44

–30

δ

ECLIPTIC

M27

θ

ωρ

M19

36

45

˚

ψ

Antares

M62

SCORPIUS THE SERPENT HOLDER

BARNARD’S STAR MOVEMENT 18h 00m

INTRICATE NEBULOSITY 4

Complex nebulosity extends from the area around Rho (ρ) Ophiuchi (at the top of the image below), southward to Antares (bottom).

MAGNITUDE KEY

17h 40m 10

71 IC 4665

66

8

˚

6

˚

`

2050 2000 1950

a

0.0–0.9 1.0–1.9 2.0–2.9

67 70

˚

4

˚

0

˚

68

3.0–3.9 4.0–4.9 5.0–5.9 6.0–6.9

MYTHS AND STORIES

ASCLEPIUS

M10 15

SNAKE MAN 2

Ophiuchus represents a man wrapped in the coils of a huge snake, the constellation Serpens. The ecliptic runs through Ophiuchus, and planets can be seen within its borders.

RESTORATIVE POWERS

Asclepius is watched as he heals a female patient, in this 5th-century BC marble relief from Piraeus, Greece.

T HE N I G H T S K Y

The large globular cluster M10 is some 14,000 light-years away. Like its neighbor M12, it is detectable through binoculars on a clear night.

Ophiuchus is identified with Asclepius, the Greek god of medicine who reputedly had the power to revive the dead. Hades, god of the Underworld, feared that this ability endangered his trade in dead souls and asked Zeus to strike Asclepius down. Zeus then placed the great healer among the stars.

382

THE CONSTELLATIONS

19h

18h

AQUILA

OPHIUCHUS

THE SHIELD

Scutum SIZE RANKING

ηβ

84

BRIGHTEST STAR

M11

Alpha (α) 3.8 GENITIVE

Scuti

-10

˚

R

ε

δ

α ζ

M26

Sct

ABBREVIATION

HIGHEST IN SKY AT 10 PM

SCUTUM

July–August

γ

SERPENS CAUDA

FULLY VISIBLE

74°N–90°S -20

This minor constellation is situated in a rich area of the Milky Way, between Aquila and Sagittarius, south of the celestial equator. It was introduced by Johannes Hevelius (see p.384) in the late 17th century. He gave it the name Scutum Sobiescianum, meaning Sobieski’s Shield, to honor his patron, King John Sobieski of Poland. SPECIFIC FEATURES Delta (δ) Scuti is the prototype of a class of variable star that pulsates in size every few hours, changing brightness by only a few tenths of a magnitude. Delta itself varies between magnitude 4.6 and 4.8 in less than five hours, but the change is only detectable with sensitive instruments. Far more obvious is R Scuti, an orange supergiant that rises and falls between magnitudes 4.2 and 8.6 in a 20-week cycle. Near R Scuti is the beautiful Wild Duck Cluster (M11), which appears as a smudgy glow half the apparent width of a full moon when viewed through binoculars. This open cluster gained its popular name because its

˚

SAGITTARIUS

stars form a fan THE SHIELD shape, like a flock of ducks in flight, when seen through a small telescope. Near the apex of the fan is an 8th-magnitude red giant. The Wild Duck Cluster is in an area of the constellation that is known as the Scutum Star Cloud. This rich star field is located just south of Beta (β) Scuti. WILD DUCKS 15

Seen through a small telescope, M11 looks like the V-shaped flight pattern of wildfowl. This effect is less apparent on photographs.

SOBIESKI’S SHIELD 2

Scutum has no bright stars of its own, but it lies in an area of the Milky Way, between Aquila and Sagittarius, that is particularly rich with stars.

SCUTUM STAR CLOUD 21

One of the brightest parts of the Milky Way lies in Scutum and is known as the Scutum Star Cloud. The bright spot at center left is the Wild Duck Cluster.

THE ARROW

Sagitta SIZE RANKING

86

BRIGHTEST STAR

Gamma (γ) 3.5 GENITIVE

Sagittae

ABBREVIATION

Sge

HIGHEST IN SKY AT 10 PM

August FULLY VISIBLE

TH E N I G H T S KY

90°N–69°S

Sagitta was known to the ancient Greeks, who believed it represented an arrow shot by either Apollo, Hercules, or Eros. It is the thirdsmallest constellation, lying in the Milky Way between Vulpecula and Aquila in the northern sky. It is faint and easily overlooked.

SPECIFIC FEATURES ARROW IN FLIGHT 2 There is little of note in Sagitta for The small arrow Sagitta flies over the users of small instruments. Zeta (ζ) stars of Aquila, the eagle, and toward Sagittae is a 5th-magnitude star with Delphinus, the dolphin. a 9th-magnitude companion that is visible in a small telescope, but it is not a particularly impressive double. S Sagittae is a Cepheid variable that halves in brightness every 8.4 days THE ARROW before recovering again, as it swings between magnitudes 5.2 and 6.0. Midway along the shaft of the arrow is M71, a modest globular 19h 20h cluster detectable with VULPECULA binoculars but better seen through a HERCULES telescope. M71 lacks the 20 central condensation ˚ M 71ζ γ typical of most δ α WZ globulars and instead VZ β SAGITTA looks more like a dense S open cluster. DELPHINUS WZ Sagittae is a AQUILA dwarf nova variable 10 Altair ˚ (see Novae, p.282). It is rarely in outburst.

THE CONSTELLATIONS Altair is flanked by 4th-magnitude Alshain, or Beta (β) Aquilae, and 3rdmagnitude Tarazed, or Gamma (γ) Aquilae, which form a distinctive trio.

THE EAGLE

Aquila SIZE RANKING

22

SPECIFIC FEATURES Aquila’s main feature of interest is Eta (η) Aquilae (see p.286), which is one of the brightest Cepheid variables. Eta ranges between magnitudes 3.5 and 4.4 on a cycle of 7.2 days. As with all members of this class, it is a brilliant supergiant. Its distance is estimated at 1,400 light-years. The constellation also has some faint double stars that can readily be split with a small telescope: 15 Aquilae, with stars of 5th and 7th magnitudes; and 57 Aquilae, with two 6th-magnitude components.

BRIGHTEST STAR

Altair (α) 0.8 GENITIVE

Aquilae Aql

ABBREVIATION

HIGHEST IN SKY AT 10 PM

July–August FULLY VISIBLE

78°N–71°S

Aquila depicts an eagle in flight (see panel, right). It lies on the celestial equator in a rich area of the Milky Way near Cygnus, Scutum, and Sagittarius, yet there are no deep-sky objects of particular note within it. Aquila’s brightest star, Altair or Alpha (α) Aquilae (see p.252), forms one corner of the northern Summer Triangle of stars, completed by Vega (in Lyra) and Deneb (in Cygnus).

383

MYTHS AND STORIES

WINGED CARRIERS The eagle has at least two identifications in Greek mythology. It was the bird that carried the thunderbolts for the god Zeus, and in one myth Zeus sent an eagle, or took the form of an eagle, to carry the shepherd boy Ganymede up to Mount Olympus, where he was made a servant of the gods. Zeus had spied the boy tending sheep in a field and had become infatuated with him. Ganymede is represented by neighboring Aquarius. ON EAGLE’S WINGS

The beautiful youth Ganymede is carried aloft by an eagle in Peter Paul Rubens’s 17thcentury painting The Abduction of Ganymede.

STELLAR TRIO 2

Altair, the constellation’s brightest star, is flanked by 3rd-magnitude Tarazed (top), which has a noticeably orange color, and 4th-magnitude Alshain (bottom), forming an attractive stellar trio.

THE EAGLE

THE HOOK 21

This easily recognizable group of stars in southern Aquila includes Lambda (λ) Aquilae (center left) and branches into neighboring Scutum.

19h

20h 20

VULPECULA

˚

HERCULES SAGITTA

DELPHINUS

ρ 10

˚

γ

Alshain

NGC 6709

α

ξ

ε

ζ

AQUILA Tarazed

EQUULEUS

FF

R

μ

Altair

β

δ 0

η

˚

71

θ

SERPENS CAUDA

69

AQUARIUS 57 -10

ν

κ

˚

26

λ

15 12

SCUTUM

SWOOPING ACROSS THE SKIES 2

CAPRICORNUS SAGITTARIUS

The eagle swoops across the evening skies in the second half of the year. Its main star, Altair, is the most southerly of those that form the northern Summer Triangle. Aquila points toward the stars of Capricornus.

T HE N I G H T S K Y

70

ι

384

THE CONSTELLATIONS THE FOX

22h 21h

Vulpecula SIZE RANKING

CYGNUS

THE FOX

Alpha (α) 4.4 Vulpeculae

ABBREVIATION

Vega

55

BRIGHTEST STAR

GENITIVE

19h

20h

Vul

HIGHEST IN SKY AT 10 PM

August–September FULLY VISIBLE

90°N–61°S

This small, faint northern constellation lies in the Milky Way, south of Cygnus. When it was first introduced in the late 17th century by the Polish astronomer Johannes Hevelius (see panel, below), it was

30

named Vulpecula cum Anser (the fox with the goose). Its name has since been simplified to Vulpecula. Despite its relative obscurity, it contains two unmissable objects for binocular users.

T 31 30

PEGASUS 20

SPECIFIC FEATURES The brightest star in the constellation, Alpha (α) Vulpeculae, is a 4th-magnitude red giant with a 6th-magnitude orange star nearby, which is visible with binoculars. The two lie at different distances and are unrelated. Brocchi’s Cluster is one of the binocular treasures of the sky. This grouping of ten stars, with components ranging from 5th to 7th magnitude, is better known as the Coathanger because of its shape: a line of six stars forms the bar of the hanger, while the remaining four are

˚

LYRA

˚ 23

VULPECULA 29

15

HERCULES

13 M27

α 12

1

9 BROCCHI'S CLUSTER

DELPHINUS SAGITTA

the hook. All the stars are unrelated, however, and so do not form a true cluster. The Coathanger’s shape is therefore the delightful product of a chance alignment. Popularly known as the Dumbbell Nebula, M27 is the easiest planetary nebula to spot in the sky. It appears as a rounded patch, about one-third the

size of a full moon, when viewed through binoculars. Its twin-lobed or hourglass shape is revealed only with larger instruments and on longexposure photographs. It is about 1,000 light-years away. CCD images and photographs show a variety of colors, but visually the Dumbbell appears gray-green. THE COATHANGER 1

Perhaps the most charming of all star clusters is Brocchi’s Cluster, also known as the Coathanger. This group of stars, easily visible through binoculars, appears to mark out the shape of a simple coathanger.

THE DUMBBELL NEBULA 154

TH E NI G HT S KY

Reputedly the easiest planetary nebula to spot, M27 can be found with binoculars on dark nights. A telescope is needed to make out the twin lobes that give rise to its popular name.

JOHANNES HEVELIUS Johannes Hevelius (1611-87) was born and worked in the town of Danzig, Germany (now Gdansk, Poland), where he established an observatory equipped with the finest instruments of his time. Among his legacies was a star catalog and atlas, published posthumously by his assistant and second wife, Elizabeth, introducing seven new constellations and filling the gaps in the northern skies.

FOX IN THE MILKY WAY 2

Vulpecula is a shapeless constellation sandwiched between the more easily recognizable pattern of Sagitta, the arrow, at the left of this picture, and the head of the swan, Cygnus.

JOINT EFFORT

Johannes Hevelius and his wife Elizabeth measured star positions with a large sextant. This instrument is commemorated in one of the constellations Hevelius invented, Sextans.

THE CONSTELLATIONS

385

THE DOLPHIN

Delphinus SIZE RANKING

69

BRIGHTEST STAR

Rotanev (β) 3.6 GENITIVE

Delphini

ABBREVIATION

Del

HIGHEST IN SKY AT 10 PM

August–September

GAMMA DELPHINI 5

Gamma (γ) Delphini is an attractive double star. Although both the component stars are usually described as yellow, some observers see the fainter star as bluish.

FULLY VISIBLE

90°N–69°S

stars: Sualocin (α), Rotanev (β), and Gamma (γ) and Delta (δ) Delphini. Who coined the name Job’s Coffin, and when, is not known.

This small but distinctive constellation is situated between Aquila and Pegasus. According to Greek myth, Delphinus represents the dolphin that saved the poet and musician Arion from drowning after he leaped into the sea to escape robbers onboard a ship. Alternatively, the constellation is said to depict one of the dolphins sent by Poseidon to bring the sea nymph Amphitrite to him to marry. It is one of the constellations listed by the astronomer Ptolemy (see p.347). The whole constellation was once popularly known as Job’s Coffin, presumably because of the boxlike shape of its area, although sometimes this name is restricted to the diamond asterism formed by the four brightest

SPECIFIC FEATURES Gamma (γ) Delphini is normally described as an attractive orangeyellow double star. Its components are of 4th and 5th magnitudes, and they are easily separated by 20 ˚ a small telescope. The fainter and closer double star PEGASUS Struve 2725, which has components of 7th and 8th magnitudes, can also 10 ˚ be seen through a small telescope and is visible in the same field of view as Gamma (γ) Delphini. EQUULEUS

VULPECULA HR

γ α Sualocin ζ δ Rotanev β ε

SAGITTA

Altair

NGC 6934

DELPHINUS AQUILA

0

NICCOLÒ CACCIATORE

˚

Alpha (α) and Beta (β) Delphini bear the unusual names Sualocin and Rotanev. When reversed, these names spell Nicolaus Venator. This is the Latinized name of Niccolò Cacciatore (1780–1841), an Italian astronomer who was assistant to Giuseppe Piazzi, the director of the Palermo Observatory, Sicily. Cacciatore defied convention by surreptitiously naming two stars after himself in the Palermo star catalog of 1814. No one realized what he had done until much later, by which time the star names had become established.

THE PLAYFUL DOLPHIN 2

The kite-shaped Delphinus, on the edge of the Milky Way near Cygnus, brings to mind a dolphin jumping from ocean waters.

THE DOLPHIN

been added to the sky by the Greek astronomer Ptolemy in his 2nd-century-AD compendium of the original Greek constellations.

THE FOAL

Equuleus SIZE RANKING

Alpha (α) 3.9 Equulei

ABBREVIATION

˚

S 21h

87

BRIGHTEST STAR

GENITIVE

20

Equ

HIGHEST IN SKY AT 10 PM

September FULLY VISIBLE

The second-smallest constellation in the sky represents the head of a young horse, or foal, and lies next to the larger celestial horse, Pegasus. No myths or legends are associated with Equuleus, which is thought to have

PEGASUS 10

δ γ

˚

DELPHINUS

β

α

1

EQUULEUS 0

˚ AQUARIUS THE HORSE’S HEAD 2

Equuleus consists of a small area of faint stars wedged between Pegasus and Delphinus and is easily overlooked. THE FOAL

T HE N I G H T S K Y

90°N–77°S

SPECIFIC FEATURES Gamma (γ) Equulei is a wide double star, with components of 5th and 6th magnitudes and is easily separated with binoculars. Its two stars are unrelated. The 5th-magnitude double star 1 Equulei—labeled as Epsilon (ε) Equulei on some maps—has a 7th-magnitude companion, which can be seen through a small telescope, and a fainter true companion, which can be seen only through instruments with larger apertures. Other than these two double stars, there is nothing of note in Equuleus for users of binoculars or small telescopes.

386

THE CONSTELLATIONS THE WINGED HORSE

Pegasus

THE GREAT SQUARE 2 SIZE RANKING

The most distinctive feature of this constellation is the Great Square of Pegasus, which forms the horse’s body.

7

BRIGHTEST STARS

Beta (β) 2.4, Epsilon (ε) 2.4 GENITIVE

Pegasi

ABBREVIATION

Peg

HIGHEST IN SKY AT 10 PM

September–October FULLY VISIBLE

90°N–53°S

Pegasus lies north of the zodiacal constellations Aquarius and Pisces, in low northern declinations, and it adjoins Andromeda. It was one of the original 48 Greek constellations. Pegasus represents the flying horse ridden by the hero Bellerophon, although he is sometimes wrongly identified as the steed of Perseus (see panel, below). Although only the forequarters of the horse are indicated by stars, the constellation is still the seventh-largest in the sky. SPECIFIC FEATURES The Great Square of Pegasus is formed by the stars Alpha (α), Beta (β), and Gamma (γ) Pegasi, plus Alpha (α) Andromedae. Long ago, the fourth star of the Square was also known as Delta (δ) Pegasi and was shared with 0h

22h

23h

LACERTA ANDROMEDA

π

NGC 7331

η

72

α And

β

78

ο

Scheat

ψ 20

υ GREAT SQUARE OF PEGASUS

˚χ Algenib

γ 10

τ

μ λ

56

PEGASUS

Markab

˚ 55

TH E NI G H T S KY

PISCES

0

ι

51

α 70

32

ξ

31

ζ

ρ

θ 35

˚ M15 15

THE WINGED HORSE

A telescope with 6-in (150-mm) aperture resolves this cluster into individual stars. It is over 30,000 light-years away.

ν

Andromeda, but now it is exclusively Andromeda’s. A line of more than 30 full moons CYGNUS would fit into the Square, yet for such a large area it is surprisingly devoid of stars, its brightest one being Upsilon (υ) Pegasi, of magnitude 4.4. κ Therefore, when the Great Square is viewed through 2 polluted skies, it may seem completely empty. The constellation’s two 1 brightest stars are Beta, a red 9 giant that varies between magnitudes 2.3 and 2.7, and Epsilon (ε) Pegasi, a yellow M15 star of magnitude 2.4 with a wide 8th-magnitude ε companion that can be seen Enif through a small telescope. Not far from Epsilon lies the globular cluster M15 (see p.295), which is one of EQUULEUS the finest such objects in northern skies. It is just at the limit of naked-eye visibility when viewed through clear skies. Just outside the Great Square of Pegasus is a 5th-magnitude star called 51 Pegasi, which was the first star beyond the Sun confirmed to have a planet in orbit around it. This planet was discovered in 1995, and its mass is about half that of Jupiter.

MYTHS AND STORIES

BELLEROPHON AND PEGASUS Pegasus the winged horse was born from the body of Medusa, the Gorgon, when she was decapitated by Perseus. He flew to Mount Helicon, home of the Muses, where he stamped on the ground and brought forth a spring called Hippocrene, the “horse’s fountain.” With the aid of a golden bridle from Athena, the hero Bellerophon tamed Pegasus, and rode the horse on his successful mission to kill the fire-breathing monster Chimaera. Bellerophon later attempted to ride Pegasus up to Olympus, to join the gods, but he fell off. The horse arrived safely. TAKING FLIGHT

Pegasus beats his wings, as though attempting to ascend to the skies, in this statue in Powerscourt Gardens, Dublin, Ireland.

0h

23h

22h

PEGASUS

387

21h

EQUULEUS

THE WATER CARRIER

Aquarius

0 SIZE RANKING

η ζ

PISCES

˚

ECL

IC

WATER JAR

BRIGHTEST STARS

χ 1 ψ2 ψ 3 ψ

GENITIVE

Aquarii Aqr

-10

˚

June–July 2

ω

FULLY VISIBLE

65°N–86°S

AQUARIUS

β

σ τ

ω1

ι

μ ε ν

NGC 7009 M73

M72

δ 66 98

˚

3

ξ

θ

λ

104 -20

M2

Sadalmelik

Sadalsuud

HIGHEST IN SKY AT 10 PM

This large constellation of the zodiac is visualized as a youth (or, sometimes, an older man) pouring water from a jar. It is is found between Capricornus and Pisces, near the celestial equator. The stars Gamma (γ), Zeta (ζ), Eta (η), and Pi (π) Aquarii form a Yshaped grouping that makes up the Water Jar, from which a stream of stars represents water flowing toward Piscis Austrinus. In early May each year, the Eta Aquarid meteor shower radiates from the area of the water jar. In Greek myths and stories, Aquarius represents Ganymede— a beautiful shepherd boy to whom the god Zeus took a fancy. Zeus dispatched his eagle (or, in some stories, turned himself into an eagle) to carry Ganymede up to Mount Olympus, where he became a waiter to the gods. The Eagle is represented by neighboring Aquila.

ο

ϕ

Sadalmelik (α) 2.9, Sadalsuud (β) 2.9

ABBREVIATION

α

γ

IPT

10

π

CAPRICORNUS

88 101

99

NGC 7293

89 86

PISCIS AUSTRINUS SCULPTOR -30

˚

SPECIFIC FEATURES Zeta—the star at the center of the Water Jar group—is a close binary of 4th-magnitude stars just at the limit of resolution with a telescope of 2.4 in (60 mm) aperture. Located near the border with Equuleus, the globular cluster M2 appears as a fuzzy star when viewed through binoculars or a small telescope. Aquarius contains two of the bestknown planetary nebulae in the sky. The Helix Nebula (NGC 7293; see p.257) is thought to be the closest planetary nebula to Earth, being some 300 light-years away. It is therefore one of the largest of such nebulae in

apparent size, at almost half the diameter of a full moon. However, because its light is spread over such a large area, the Helix Nebula can be identified only when skies are clear and dark. Visually, this nebula appears as a pale gray patch, showing none of the beautiful colors captured on photographs. The second planetary nebula— the Saturn Nebula (NGC 7009)— is easier to spot, appearing to be of a size similar to the disk of Saturn when viewed with a small telescope. Its faint extensions on either side, rather like the rings of Saturn, give rise to the object’s popular name.

THE WATER CARRIER

THE HELIX NEBULA 154

NGC 7293 is visible as a pale rounded patch through binoculars under dark skies, but its detailed structure and approximate colors are brought out in CCD images such as this.

THE SATURN NEBULA 54

NGC 7009’s resemblance to the ringed planet Saturn is most evident when it is viewed through a large telescope or on a CCD image.

The cascade of stars that represent the flow of water from Aquarius’s jar is to the left of this image. The distinctive Water Jar is center-top.

T HE N I G H T S KY

POURING WATER 2

388

THE CONSTELLATIONS Alrescha (α) is a close pair of stars of 4th and 5th magnitudes that can be separated with a telescope with an aperture of 4 in (100 mm). These two stars form a true binary with an orbital period of more than 900 years. Zeta (ζ) and Psi-1 (ψ1) Piscium are two more doubles that can be divided with a small telescope.

THE FISH

Pisces SIZE RANKING

14

BRIGHTEST STAR

Eta (η) 3.6 GENITIVE

Piscium ABBREVIATION

A beautiful face-on spiral galaxy, M74, lies just over two diameters of a full moon from the constellation’s brightest star, Eta (η) Piscium. It appears as a round, bright glow through a small telescope; the spiral arms only show up well through a telescope with larger aperture and on long-exposure photographs.

Psc

HIGHEST IN SKY AT 10 PM

October–November

THE CIRCLET 21

FULLY VISIBLE

The body of the southerly fish is marked by a ring of stars called the Circlet. One of the stars, TX Piscium, is a red giant of variable brightness, which appears noticeably orange through binoculars.

83°N–56°S

This zodiacal constellation represents two mythical fish (see panel, right). Its main claim to fame is that it contains the vernal equinox, which is the point where the Sun crosses the celestial equator into the Northern Hemisphere each year in March— on star maps, this is where 0h right ascension intersects 0º declination. Because of the slow wobble of the Earth, known as precession (see p.64), the point of the vernal equinox is gradually moving along the celestial equator and will enter Aquarius in about ad 2600.

DIVERGENCE 2

Pisces represents a pair of fish tied together by their tails with ribbon. The point where the two ribbons are knotted together is marked by the star Alpha (α) Piscium. MYTHS AND STORIES

EROS AND APHRODITE Ancient Greek myths concerning the origins of the constellation of Pisces are rather vague. In one myth, Aphrodite and her son Eros transformed themselves into fish and plunged into the Euphrates to escape the fearsome monster Typhon. In another version of the same story, two fish swam up and carried Aphrodite and Eros to safety on their backs.

SPECIFIC FEATURES The most distinctive feature of Pisces is the ring of seven stars lying south of the Great Square of Pegasus. Known as the Circlet, this ring marks the body of one of the fish. It includes TX Piscium (also known as 19 Piscium), a deep-orange-colored red giant that fluctuates irregularly between magnitudes 4.8 and 5.2. 2h 1h

TRIANGULUM 30

˚

τ υ ϕ

20

χ

˚

ψ1 ψ2

ψ3

ARIES

RESCUE AT SEA

TV

M74

THE FISH

η

TH E N I G H T S KY

10

PISCES

˚

ο

ζ ν

α Alrescha 0

˚

PEGASUS

ε

δ ω

μ ECL

TX IPT

ξ

CETUS

IC

ι

θ

7

CIRCLET

λ

κ

27 33 30

AQUARIUS

γ

β

M74 54

The spiral galaxy M74 is seen face-on and appears as a rounded glow when viewed through a small telescope. Larger apertures are needed to see its spiral arms.

In this 17th-century painting by the Flemish artist Jacob Jordaens, Aphrodite and Eros are carried away on the back of a fish.

THE CONSTELLATIONS THE SEA MONSTER

Cetus SIZE RANKING

4

BRIGHTEST STAR

Diphda or Deneb Kaitos (β) 2.0 GENITIVE

Ceti

ABBREVIATION

Cet

HIGHEST IN SKY AT 10 PM

October–December FULLY VISIBLE

65°N–79°S

Cetus is represented on old star charts as an unlikely-looking, almost comical, hybrid sea monster, although the figure is also sometimes referred to as a whale. It is one of the original 48 Greek constellations listed by Ptolemy in his Almagest. It is a large but not very obvious constellation found in the equatorial region of the sky, and it lies south of the zodiacal constellations Pisces and Aries. Cetus is home to the celebrated variable star, Mira (ο) (see p.285), as well as a peculiar spiral galaxy, M77. SPECIFIC FEATURES Menkar (α) is the second-brightest star in the constellation. It forms part of the loop of stars that mark the sea monster’s head, and it has a wide and unrelated 6th-magnitude companion that is visible through binoculars. Positioned near the neck of the sea monster is Gamma (γ) Ceti, a close THE SEA MONSTER

double star that is more challenging to divide than Menkar. High magnification on a telescope is required to see the two component stars, of 4th and 7th magnitudes. Mira (ο) is the prototype of a common type of red giant that pulsates in size over months or years. Mira can reach magnitude 2 at its brightest—although magnitude 3 is more usual—while at its faintest it drops to magnitude 10. Hence, depending on how much it has swollen or contracted within its 11-month cycle, Mira can be either a naked-eye star or one that is visible only with a telescope.

10

Because it is a Seyfert galaxy, the spiral galaxy M77 looks like a fuzzy star through smaller telescopes—only its extremely bright core can be seen.

Tau (τ) Ceti is 11.9 light-years away. Its temperature and brightness make it the most Sun-like of all Earth’s nearby stars. Tau is, however, surrounded by a swarm of asteroids and comets, which would subject any local planets to 2h

devastating bombardments. Thus the prospects for life in its vicinity seem rather slim. M77 is found near Delta (δ) Ceti. This spiral galaxy is the brightest example of a Seyfert galaxy (see Types of Active Galaxies, p.320). Related to quasars, Seyfert galaxies are a class of galaxies that have extremely bright centers. M77 is oriented face-on toward the Earth, although only its core is visible through a small telescope, and it looks only like a small, round patch. M77 lies just under 50 million light-years away.

PISCES

˚

μ

λ κ 0

M77 54

3h

TAURUS

389

α

ξ

1

ξ

0h

ν

Menkar

γ

ECL

IPT

IC

δ

M77

˚

2

20

ο

Mira

-10

˚ π

-20

˚

ε

ρ

ζ

AQUARIUS

CETUS

θ

ERIDANUS

η

ϕ

ι 3

NGC 246

σ

46

τ υ

6

β Diphda

7

2

56

FORNAX

SCULPTOR

MYTHS AND STORIES

THE SEA MONSTER Cetus was the sea monster sent to devour the princess Andromeda in the famous Greek myth (see p.368). On his return from killing Medusa the Gorgon, Perseus spied Andromeda’s plight and swooped down on the sea monster as it attacked, stabbing it repeatedly with his sword in a fury of blood and foam, and leaving its waterlogged corpse on the beach for the local people to pillage.

Cetus is large but not particularly prominent. Its most celebrated star is the variable red giant Mira (ο), which for much of the time is too faint to be seen with the naked eye.

MYTHICAL MONSTER

Old star charts depict Cetus with enormous jaws and a coiled tail, its flippers dipped in the neighboring constellation, the river Eridanus.

T HE N I G H T S K Y

LURCHING MONSTER 2

390

THE CONSTELLATIONS SPECIFIC FEATURES Marking one shoulder of Orion is Betelgeuse—Alpha (α) Orionis (see p.256) —a red supergiant hundreds of times larger than the Sun. Betelgeuse varies irregularly in brightness between magnitudes 0.0 and 1.3, but it averages around magnitude 0.5. It is about 500 light-years away, and it is closer to Earth than any of the other bright stars in Orion.

THE HUNTER

Orion SIZE RANKING

26

BRIGHTEST STARS

Rigel (β) 0.2, Betelgeuse (α) 0.5 GENITIVE

Orionis

ABBREVIATION

Ori

Betelgeuse contrasts noticeably in color with Rigel—Beta (β) Orionis—an even more luminous blue supergiant, which marks one of Orion’s feet. Apart from the rare times when Betelgeuse is at its maximum magnitude, Rigel is the brightest star in the constellation. Rigel lies 860 light-years from Earth—almost twice as far away as Betelgeuse. Its 7th-magnitude companion can be

picked out from its surrounding glare using a small telescope. Two other easily seen double stars are in Orion’s belt. Delta (δ) Orionis has a 7thmagnitude companion, which is visible through a small telescope or binoculars. It is a greater challenge to reveal the close 4th-magnitude companion of Zeta (ζ) Orionis—this requires a telescope with an aperture of at least 3 in (75 mm).

HIGHEST IN SKY AT 10 PM

December–January FULLY VISIBLE

79°N–67°S

Orion is one of the most glorious constellations in the sky, representing a giant hunter or warrior followed by his dogs, Canis Major and Canis Minor (see panel, below). Its most distinctive feature is Orion’s belt, formed by a line of three 2ndmagnitude stars almost exactly on the celestial equator. A complex of stars and nebulosity represents the sword that hangs from Orion’s belt and contains the great star-forming region of M42, the Orion Nebula (p.241). In October each year, the Orionid meteors seem to radiate from a point near Orion’s border with Gemini.

MULTIPLE COMPANIONS 5

Sigma (σ) Orionis is a remarkable multiple star with three fainter companions—two on one side and an even fainter one on the opposite side—appearing rather like a planet orbited by moons.

MYTHS AND STORIES

T HE N I G H T S KY

THE GREAT HUNTER In Greek mythology, Orion was a tall and handsome man and the son of Poseidon, god of the sea. The Greek poet Homer, in his Odyssey, described Orion as a great hunter who brandished a club of bronze. Despite his hunting prowess, Orion was killed by a mere scorpion, some say in retribution for his boastfulness. In the sky, Orion is placed opposite the constellation of Scorpius and, each night, the hunter flees below the horizon as the scorpion rises. HUNTER AND WARRIOR

This depiction of Orion is from an ancient manuscript based on the Book of Fixed Stars, which was written by the Arabic astronomer al-Sufi around AD 964.

BRIGHT HUNTER 2

Orion, the hunter, is one of the most magnificent and easily recognizable constellations. A line of three stars makes up his belt, while an area of star clusters and nebulae forms his sword.

391 The real treasures of this constellation lie in the area around Orion’s sword. NGC 1981, for example, appears as a large, scattered cluster of stars through binoculars; its brightest stars are of 6th magnitude. NGC 1977 is an elongated patch of nebulosity surrounding the stars 42 and 45 Orionis. Nearby is the Orion Nebula, an enormous star-forming cloud of gas, 1,500 light-years away, covering an area of sky wider than two diameters of a full moon. Its glowing gas appears multicolored on photographs and CCD images, yet visually it looks only gray-green because the eye is not sensitive to colors in

faint objects. On clear nights, it appears to the naked eye as a hazy patch of light, and is obvious through any form of optical aid. An extension of the Orion Nebula bears a separate number, M43, but both are part of the same cloud. At the center of M42 lies a multiple star, Theta-1 (θ1) Orionis (see p.281), better known as the Trapezium because it appears as a group of four stars of 5th to 8th magnitude when seen through a small telescope. To one side of the nebula lies Theta-2 (θ2) Orionis, a double star with components of 5th and 6th magnitudes that can be separated with binoculars. At the tip of Orion’s sword lies Iota (ι) Orionis, a double, with components of 3rd and 7th magnitudes, divisible with a small telescope. Struve 747 is a wider double star nearby, with components of 5th and 6th magnitudes. Even more impressive is the multiple star Sigma (σ) Orionis (p.281). A small telescope shows that the main 4th-magnitude star has two 7th-magnitude companions on one side and a closer 9th-magnitude component on the other. Extending from the belt star Zeta (ζ) Orionis is a strip of bright nebulosity, IC 434, against which is silhouetted the Horsehead Nebula (see p.240). This is probably the bestknown dark nebula in the sky, and it shows well on photographs. To see it visually requires a large telescope and a dark viewing site.

THE HUNTER

7h 6h

ν

15

ORION

˚

μ Betelgeuse

λ ϕ1 ϕ2 γ

α

32

ω

MONOCEROS 56 0

˚

51

M78 NGC 2024 IC 434

δ ε ζ σ

Bellatrix

ψ223 ψ1 ρ

˚

–4

˚

NGC 1981

1.0–1.9 45

42 NGC 1977

M43

2

–6

θ

˚

θ1Trapezium M42 ι

2.0–2.9 3.0–3.9

Struve 747

4.0–4.9 49

υ

To the naked eye and through binoculars, the Orion Nebula (M42) appears only as a misty patch, south of Orion’s belt, its heart lit up by newborn stars. Its full beauty and its pinkish color become apparent only on photographs and CCD images such as this.

5.0–5.9 6.0–6.9

CANIS MAJOR

11

ο1

2

ο π1 2 π π3

π4

π6 π5

29

τ β

ERIDANUS

Rigel

LEPUS

˚ THE HORSEHEAD NEBULA 43

Looking like a knight in a celestial chess game, the Horsehead Nebula is a curiously shaped dark dust cloud silhouetted against IC 434, a backdrop of glowing hydrogen. It lies to the south of Zeta (ζ) Orionis (center left) in Orion’s belt.

TH E N I G HT S KY

-20

0.0–0.9

η

κ

Sirius

THE ORION NEBULA 54

5h 30m

22

31

M 42

-10

5h 40m

MAGNITUDE KEY

Aldebaran

TAURUS

69

10

THE ORION NEBULA REGION

U

NGC 2175

ξ

At the heart of the Orion Nebula lies a multiple star called the Trapezium (θ 1) (center, right). Its four stars are visible through small telescopes, but with larger apertures, two additional stars can also be seen.

5h

χ2 χ1

GEMINI

THE TRAPEZIUM 54

392

THE CONSTELLATIONS THE GREATER DOG

Canis Major SIZE RANKING

43

BRIGHTEST STARS

Sirius (α) -1.4, Adhara (ε) 1.5 GENITIVE

Canis Majoris CMa

ABBREVIATION

HIGHEST IN SKY AT 10 PM

January–February FULLY VISIBLE

56°N–90°S

This southern constellation contains the brightest star in the entire sky: Sirius, or Alpha (α) Canis Majoris (see p.248). It forms a triangle with Procyon (in Canis Minor) and Betelgeuse (in Orion). Canis Major was known to the ancient Greeks as one of the two dogs following Orion, the hunter (see panel, below).

SPECIFIC FEATURES Sirius is a more powerful star than the Sun, giving out about 20 times as much light, and it is among the closest stars to Earth, being 8.6 light-years away. In combination, these factors give Sirius an apparent brightness twice that of the secondbrightest star, Canopus (in Carina). Sirius is accompanied by a faint white dwarf, Sirius B (see p.268), which orbits it every 50 years. M41 is a large open cluster that is visible as a hazy patch to the naked eye. Its stars, which are scattered over an area about the size of a full moon, are revealed with binoculars, while telescopes show chains of stars radiating from its center. Around Tau (τ) Canis Majoris is NGC 2362, which is best viewed with a telescope. Also nearby is UW Canis Majoris, an eclipsing binary.

-10°

NGC 2362 5

The brightest member of this neat cluster of stars is the 4th-magnitude blue supergiant Tau (τ) Canis Majoris, which is almost at its center.

71

BRIGHTEST STAR

Procyon (α) 0.4 GENITIVE

THE GREATER DOG

SPECIFIC FEATURES Procyon is the eighth-brightest star in the sky. It is somewhat cooler and fainter than the other dog star, Sirius, and also more distant, lying 11.4 light-years away. It has a white dwarf partner, Procyon B, which is visible only with a very large telescope.

THE LITTLE DOG

CMi 7h

8h

February

GEMINI

89°N–77°S 6

T HE N I G H T S K Y

CANCER

Canis Minor is one of the original Greek constellations and lies virtually on the celestial equator. It is usually identified as the smaller of Orion’s two hunting dogs. The constellation is easily identified by its brightest star— Procyon, or Alpha (α) Canis Minoris (see p.284)—which forms a large sparkling triangle with two other 1st-magnitude stars: Betelgeuse (in Orion) and Sirius (in Canis Major). Other than that, the constellation contains little of particular note to small telescope users.

HYDRA

Procyon

M41

UW NGC 2362

27

COLUMBA

The great dog stands on its hind legs in the sky, holding brilliant Sirius in its jaws like a sparkling ball.

FULLY VISIBLE

LEPUS

15

PUPPIS

ORION’S HUNTING DOG 2

HIGHEST IN SKY AT 10 PM

-20°

Adhara

Canis Minoris ABBREVIATION

Sirius

-30°

This mythical dog was so swift that no prey could escape it, except for the Teumessian Fox, which was destined never to be caught. Laelaps was sent off in pursuit of the fox, which was FACING LEFT creating havoc near the town of In common with Thebes, north of Athens, but it was many other older an unending chase. Zeus ended the depictions of the pursuit by turning them both to constellations, Canis stone, and placed the dog in the sky Major is shown here as Canis Major—but without the fox. as a mirror image.

Canis Minor

ORION

NGC 2360

LAELAPS

THE LITTLE DOG

MONOCEROS CANIS MAJOR

MYTHS AND STORIES

SIZE RANKING

6h

7h

10

˚

CANIS MINOR 0

˚

MONOCEROS

LONE STAR 2

Unlike the distinctive constellation of the Greater Dog, Canis Minor consists of little more than its brightest star, Procyon.

THE CONSTELLATIONS THE UNICORN

Monoceros SIZE RANKING

35

BRIGHTEST STAR

Alpha (α) 3.9 GENITIVE

Monocerotis ABBREVIATION

Mon

HIGHEST IN SKY AT 10 PM

January–February FULLY VISIBLE

78°N–78°S

Monoceros is often overlooked, because it is overshadowed by neighboring Orion, Gemini, and Canis Major. It is easy to locate, however, since it is situated on the celestial equator in the middle of the large triangle formed by the brilliant 1st-magnitude stars Betelgeuse (in Orion), Procyon (in Canis Minor), and Sirius (in Canis Major).

Although none of the stars of Monoceros is bright, the Milky Way passes through it and it contains many deep-sky objects of interest. The constellation was introduced in the early 17th century by the Dutch astronomer and cartographer Petrus Plancius and depicts the unicorn, a mythical animal with religious symbolism.

well only on CCD images and photographs. NGC 2264 is another combination of open cluster and nebula. This triangular group can be seen through binoculars or a small telescope. Its brightest member is 5th-magnitude S Monocerotis—an intensely hot and luminous star that is slightly variable. CCD images and photographs show a surrounding nebulosity into which encroaches a dark wedge called the Cone Nebula (see p.242). M50 is an open cluster about half the apparent size of a full moon. It is visible through binoculars, but a telescope is needed to resolve its individual stars. NGC 2232 is larger and more scattered, and its brightest stars are visible through binoculars.

SPECIFIC FEATURES Beta (β) Monocerotis (see p.281) is regarded as one of the finest triple stars in the sky for small instruments. It is readily separated to show an arc of three 5th-magnitude stars. The double star Epsilon (ε) Monocerotis is labeled 8 Monocerotis on some charts. Its components, of 4th and 7th magnitudes, are easily spotted through a small telescope. Prime among Monoceros’s most celebrated clusters and nebulae is NGC 2244, an elongated group of stars of 6th magnitude and fainter. Surrounding the cluster is a glorious nebula known as the Rosette Nebula, although it is faint and seen

393

THE CONE NEBULA 543

This tapering region of dark gas and dust intrudes into brighter nebulosity at the southern end of the star cluster NGC 2264. The Cone Nebula is visible only on images taken with a large telescope, as here.

FRAMED BEAST 2

Monoceros occupies the space within the bright triangle of stars formed by Sirius (seen here at upper right), Betelgeuse (upper left), and Procyon (bottom center). THE ROSETTE NEBULA 54

The flowerlike form of the Rosette Nebula glows like a pink carnation in this CCD image. At its center is the star cluster NGC 2244, which can readily be identified through binoculars.

THE UNICORN 8h

6h

7h

GEMINI 10

˚

CANCER

NGC 2264

S NGC 2261

13

17 Procyon

0

NGC 2237

CANIS MINOR

18

Betelgeuse

8

NGC 2244

NGC 2301

˚ 28

19

27

20

ORION

NGC 2232

MONOCEROS 3

NGC 2353

CANIS MAJOR

LEPUS Sirius

-20°

T HE N I G H T S K Y

M50

-10°

394

THE CONSTELLATIONS MYTHS AND STORIES

THE WATER SNAKE

HERCULES AND THE HYDRA

Hydra SIZE RANKING

1

BRIGHTEST STAR

Alphard (α) 2.0 GENITIVE

Hydrae

ABBREVIATION

Hya

HIGHEST IN SKY AT 10 PM

February–June FULLY VISIBLE

54°N–83°S

The Hydra was a serpent with nine heads, one of them immortal, which lived in a swamp near the town of Lerna, emerging to ravage crops and cattle. As the second of his labors, Hercules was sent to kill the monster. He flushed it from its lair with flaming arrows and cut off each head in turn, ending with the immortal head, which he buried under a rock. DEADLY BLOWS

Hydra depicts the multiple-headed monster that fought and was killed by Hercules in the second of his labors (see panel, right). During the struggle, a crab joined forces with the Hydra but was crushed underfoot by Hercules; it was later commemorated as the constellation Cancer. Although the Hydra had nine heads, it is represented in the sky with a single head—presumably its immortal one. The constellation is the largest of all 88 and stretches for more than a quarter of the way around the sky from its head, south of Cancer and just north of the celestial equator, to its tail in the Southern Hemisphere between Libra and Centaurus. Despite its size, there is little to mark out this constellation other than a group of six stars of modest brightness, which forms the head of the water snake. SPECIFIC FEATURES Hydra’s brightest star is 2nd-magnitude Alphard, or Alpha (α) Hydrae. Alphard means “the solitary one,” and this name reflects its position in an otherwise blank area of sky. This orange-colored giant is in fact the only star in the constellation brighter than magnitude 3.0. It is about 175 light-years away. Epsilon (ε) Hydrae is a close binary star with components of contrasting colors that can be

Hercules battles with the Hydra in this sculpture by François-Joseph Bosio (1768–1845), which is exhibited in the Tuileries gardens, Paris.

divided with a telescope with an aperture of at least 3 in (75 mm) and high magnification. The yellow and blue component stars are of magnitude 3.4 and 6.7 and have an orbital period of nearly 1,000 years. M48 is an open star cluster on the border with Monoceros. It lies nearly 2,000 light-years away. M48 is larger than a full moon and it is seen well through binoculars or a small telescope. It contrasts with the globular cluster M68 (see p.295), which resembles a fuzzy star when viewed through binoculars or a small telescope. M83 is a spiral galaxy, toward the Hydra’s tail, that lies about 15 million light-years away. Through a small telescope, it appears as an elongated glow, but a telescope of larger aperture will reveal its spiral structure and its noticeable central “bar,” which may be similar to the bar that is thought to lie across the center of the Milky Way Galaxy. The planetary nebula known as the Ghost of Jupiter, or NGC 3242, is to be found near the star Mu (μ) Hydrae, in the central part of Hydra’s body.

LONG SERPENT 2

The Hydra’s head, at the right in this photograph, lies south of Cancer while the tip of its tail lies far to the left, south of the stars of Libra.

T HE N I G H T S K Y

THE GHOST OF JUPITER 54

-20°

When viewed through a small telescope, the planetary nebula NGC 3242 appears as an ethereal, bluegreen, elliptical glow about the size of the planet Jupiter, hence its popular name—the Ghost of Jupiter.

LIBRA 54 58 -30°

M83 54

This magnificent face-on spiral galaxy is to be found lying on the border of Hydra and Centaurus. M83 has a central “bar” of stars and gas, and it is sometimes known as the Southern Pinwheel.

52

395

8h 10h Regulus

CANCER

10°

LEO

0

˚ SEXTANS

11h

M48

Alphard

-10°

27

CRATER

26

U

6 12

13h NGC 3242

14h

9

HYDRA

CORVUS R

M68

PUPPIS PYXIS

M83

51

ANTLIA CENTAURUS

THE WATER SNAKE

T HE N I G H T S K Y

2

396

THE CONSTELLATIONS this case, an air pump designed by the French physicist Denis Papin for his experiments on gases.

THE AIR PUMP

Antlia SIZE RANKING

62

BRIGHTEST STAR

Alpha (α) 4.3 GENITIVE

Antliae Ant

ABBREVIATION

HIGHEST IN SKY AT 10 PM

March–April FULLY VISIBLE

49°N–90°S

This constellation was one of those introduced in the mid-18th century by the French astronomer Nicolas Louis de Lacaille (see p.422) to commemorate scientific and technical inventions—in

SPECIFIC FEATURES Zeta (ζ) Antliae appears as a wide pair of 6th-magnitude stars when viewed through binoculars. The brighter of the pair has a companion of 7th magnitude. NGC 2997 is an elegant spiral galaxy inclined at about 45 degrees to our line of sight. Unfortunately, it is just too faint to be well seen through a small telescope, although it can be captured beautifully on photographs and CCD images. NGC 2997 is about 35 million light-years away.

10h

11h

CRATER

-30°

HYDRA

NGC 2997

ANTLIA

THE AIR PUMP

-40°

VELA

NGC 2997 54

This classic spiral galaxy reveals pink clouds of hydrogen gas dotted along its spiral arms in CCD images.

NORTH OF VELA 2

Antlia is an inconspicuous grouping in the Southern Hemisphere and consists of a handful of stars to be found between Vela and Hydra.

THE SEXTANT

Sextans

10 SIZE RANKING

˚

IC

IPT

ECL

47

LEO

BRIGHTEST STAR

Alpha (α) 4.5 GENITIVE

SEXTANS

Sextantis

ABBREVIATION

0

Sex

HYDRA

˚

HIGHEST IN SKY AT 10 PM

March–April FULLY VISIBLE

78°N–83°S

NGC 3115

18

-10°

TH E N I G H T S KY

Representing a sextant used for taking star positions in the days before telescopes were invented, Sextans was introduced in the late 17th century by the Polish astronomer Johannes Hevelius (see p.384), who used such a device when cataloging the stars. SPECIFIC FEATURES Two unrelated stars of 6th magnitude, 17 and 18 Sextantis, form a line-ofsight double star, which shows neatly through binoculars. In the same part of the constellation lies NGC 3115, which is popularly named the Spindle Galaxy because of its highly elongated shape. This lenticular galaxy is detectable through a small telescope.

17

CRATER 11h

10h THE SEXTANT

HEVELIUS’S SEXTANT 2

Sextans is difficult to pick out with the naked eye because it is a faint and unremarkable constellation. It lies on the celestial equator south of Leo.

THE SPINDLE GALAXY 54

NGC 3115 is a lenticular galaxy seen edge-on from Earth, so it appears highly elliptical in shape when viewed through a telescope. It is just over 30 million light-years from us.

VIRGO

11h

12h

THE CONSTELLATIONS

SEXTANS

397

MYTHS AND STORIES

THE CUP

Crater SIZE RANKING

53

-10°

CROW AND CUP

CRATER

Crater and Corvus feature together in a Greek myth in which the god Apollo sent the crow (Corvus) to fetch water in a cup (Crater). On the way, the greedy crow stopped to eat figs. As an alibi, the crow snatched up a water snake (Hydra) and blamed it for delaying him, but Apollo saw through the deception and banished the trio to the skies.

BRIGHTEST STAR

Delta (δ) 3.6 GENITIVE

Crateris Crt

ABBREVIATION

CORVUS

HYDRA

THE CUP

HIGHEST IN SKY AT 10 PM

-20°

April FULLY VISIBLE

65°N–90°S

HISTORIC DEPICTION

Crater is a faint constellation representing a cup. Although larger than Corvus, to which it is linked in Greek myth (see panel, right), Crater contains no objects that might be of interest to users of small telescopes. This area once contained two other constellations that have since been dropped by astronomers. In the late 18th century, a French astronomer, J. J. Lalande, introduced Felis, the cat, between Hydra and Antlia, while others introduced Noctua, the night owl, on the tail of Hydra (see panel illustration, right).

The area around Crater as shown in Urania’s Mirror, a set of 19th-century constellation cards.

-30°

CELESTIAL VESSEL 2

Crater is to be found lying next to Corvus on the back of Hydra, the water snake. This undistinguished constellation is also known as the Goblet or the Chalice.

THE CROW

13h

Corvus

12h

VIRGO SIZE RANKING

70

Spica

BRIGHTEST STAR

CORVUS

Gamma (γ) 2.6 GENITIVE

CRATER

Corvi

ABBREVIATION

NGC 4038/9

Crv -20°

HIGHEST IN SKY AT 10 PM

THE CROW

April–May FULLY VISIBLE

65°N–90°S

THE ANTENNAE 43

The four brightest stars of Corvus— Beta (β), Gamma (γ), Delta (δ), and Epsilon (ε) Corvi—form a distinctive keystone shape in this small constellation south of Virgo. Oddly, the star labeled Alpha (α) Corvi, at magnitude 4.0, is significantly fainter than all of these. Corvus is one of the original 48 Greek constellations and represents a crow, the sacred bird of the Greek god Apollo.

-30°

HYDRA

PECKING BIRD 2

Corvus, the crow, is linked in legend with neighboring Crater, the cup. The crow is visualized as pecking at Hydra, the water snake, on whose back it stands.

T HE N I G H T S K Y

SPECIFIC FEATURES Delta is a double star with components of 3rd and 9th magnitudes. It is divisible through a small telescope. Corvus also boasts a remarkable pair of interacting galaxies: NGC 4038 and 4039. At 10th magnitude, they are too faint to be seen through a small telescope, but photographs reveal this as a graphic example of a galactic collision. When the galaxies passed each other, gravity pulled out stars and gas to create a shape like an insect’s feelers, hence their popular name, the Antennae (see p.317).

As NGC 4038 and 4039 sweep past each other, gravity draws out long streams of dust and gas from them. The streams extend off the top and bottom of this picture.

398

THE CONSTELLATIONS

13h

14h

LIBRA

12h

11h

CORVUS HYDRA

THE CENTAUR

Centaurus

-30° SIZE RANKING

4

9

3

BRIGHTEST STARS

1 2

ANTLIA

Rigil Kentaurus (α) -0.3, Hadar (β) 0.6 GENITIVE

CENTAURUS

Centauri

ABBREVIATION

-40°

Cen

HIGHEST IN SKY AT 10 PM

April–June

NGC 5128

THE CENTAUR

FULLY VISIBLE

25°N–90°S

This dominating constellation of the southern skies contains a variety of notable objects, including the closest star to the Sun and a most unusual galaxy. Centaurus represents the centaur Chiron (see panel, right), who had the torso of a man and the four legs of a horse. SPECIFIC FEATURES Alpha (α) Centauri (see p.252), or Rigil Kentaurus, is a fabulous multiple star. To the naked eye, it is the thirdbrightest star in the sky. Its system includes two Sun-like stars, which appear so bright because they are only 4.3 light-years away, closer than any other stars bar one—Proxima Centauri (see p.252), which is about 0.1 light-years closer. However, Proxima is of only magnitude 11 and lies four diameters of a full moon away from its brighter companions. Its position means it is outside Alpha’s telescopic field of view, so identification is difficult.

Although it bears a Greek letter, Omega (ω) Centauri is not a star but a globular cluster, the largest and brightest visible from Earth.To the naked eye, it is a large, hazy star, and a small telescope is required to resolve the brightest individual members of this globular cluster. Almost due north of Omega is the peculiar galaxy NGC 5128, also known as the radio source Centaurus A (see p.322). This object is thought to result from the merger of a giant elliptical galaxy and a spiral galaxy. Photographs show a dark band of dust across the galaxy’s center, the remains of the spiral galaxy, but larger apertures are needed to make out this feature visually. NGC 5128 is the brightest galaxy outside the Local Group and, at a distance of about 12-million light-years, is the closest peculiar galaxy to us. The planetary nebula NGC 3918, or the Blue Planetary, is easily identified through a small telescope. It appears like a larger version of the disk of Uranus. Also in Centaurus are two interesting open star clusters NGC 3766 and NGC 5460.

NGC 5139

LUPUS

NGC 4945

NGC 5460

VELA

CRUX CIRCINUS R

NGC 3918

Hadar NGC 3766

Rigil Kentaurus Acrux

TRIANGULUM AUSTRALE

MUSCA CARINA

MYTHS AND STORIES

CHIRON The wise and scholarly centaur Chiron was the offspring of Cronus, king of the Titans, and the sea nymph Philyra. He lived in a cave, from where he taught hunting, medicine, and music to the offspring of the gods. His most successful pupil was Asclepius, son of Apollo, who became the greatest healer of the ancient world. Chiron was immortalized among the stars after Heracles accidentally shot him with a poisoned arrow. TEACHER OF THE GODS

TH E N I G H T S KY

This Roman fresco shows Chiron teaching Achilles, his foster son, to play the lyre. They are in Chiron’s cave on Mount Pelion.

ALPHA CENTAURI 5

The two yellow stars, of magnitudes 0.0 and 1.3, of this beautiful double star orbit each other every 80 years. They are easily separated through a small telescope. CELESTIAL CENTAUR 2

The brilliant stellar pairing of Alpha (α) and (β) Beta Centauri guides the eye to Centaurus, the celestial centaur. The familiar pattern of Crux, the Southern Cross, lies beneath the centaur’s body.

THE CONSTELLATIONS THE WOLF

Lupus SIZE RANKING

46

BRIGHTEST STAR

Alpha (α) 2.3 GENITIVE

Lupi

ABBREVIATION

Lup

HIGHEST IN SKY AT 10 PM

May–June FULLY VISIBLE

34°N–90°S

magnitude companion visible through a small telescope. Its primary star, however, is a close double, needing an aperture of at least 4 in (100 mm) to separate. The 3rd-magnitude Epsilon (ε) Lupi has a companion of 9th magnitude, and Eta (η) Lupi is a 3rd-magnitude star with an 8thmagnitude companion. NGC 5822 is a rich open cluster within the Milky Way. Its brightest stars are of only 9th magnitude, so it is not particularly prominent. It lies 2,400 light-years away.

15h Antares

LIBRA 2

SCORPIUS

ξ

SPECIFIC FEATURES Kappa (κ) Lupi, with components of magnitudes 3.9 and 5.7, and Xi (ξ) Lupi, with components of magnitudes 5.1 and 5.6, are two doubles that are easy to spot through a small telescope. Pi (π) Lupi can be divided into matching 5th-magnitude components through a telescope with an aperture of 3 in (75 mm). Even more challenging is 4th-magnitude Mu (μ) Lupi, which has a wide 7th-

HYDRA

1

CENTAURUS

NGC 5986

-40 °

GG

-50°

Lupus is a southern constellation lying on the edge of the Milky Way between the better-known figures of Centaurus and Scorpius. It contains numerous double stars of interest to amateur observers. It was one of the original 48 constellations familiar to the ancient Greeks, who visualized it as a wild animal speared by Centaurus (see panel, below).

399

NORMA

LUPUS THE WOLF NGC 5822

CIRCINUS -60°

NGC 5822 5

This large open cluster in southern Lupus contains more than 100 stars of 9th magnitude and fainter. It can be seen through binoculars or a small telescope.

Hadar Rigil Kentaurus A

MYTHS AND STORIES

THE LANCED BEAST To the ancient Greeks and Romans, Lupus represented a wild animal of unspecified nature that had been speared, by neighboring Centaurus, on a long pole called a thyrsus. In consequence, Centaurus and Lupus were often regarded as a combined figure. The identification of Lupus as a wolf seems to have become common during Renaissance times. IN MIRROR IMAGE

This medieval Arabic illustration shows Centaurus holding Lupus and the thyrsus, which has become a bunch of leaves or flowers.

Here, Lupus is partly surrounded by the stars of Centaurus. In Greek myth, the centaur killed the beast and carried it to the altar, Ara.

T HE N I G H T S K Y

BESTIAL OFFERING 2

400

THE CONSTELLATIONS THE ARCHER

Sagittarius SIZE RANKING

15

BRIGHTEST STAR

Epsilon (ε) 1.8 GENITIVE

Sagittarii

ABBREVIATION

Sgr

HIGHEST IN SKY AT 10 PM

July–August FULLY VISIBLE

44°N–90°S

This prominent zodiacal constellation is found between Scorpius and Capricornus, in the southern celestial hemisphere. It includes a highly recognizable star pattern called the Teapot, with a pointed lid (λ) and large spout (γ, ε, and δ). The handle of the Teapot is sometimes also called the Milk Dipper. The Milky Way is particularly broad and rich in Sagittarius, because the center of our Galaxy (Sagittarius A) lies in this direction. The exact center of the Galaxy is thought to coincide with a radio source known as Sagittarius A*, near where the borders of Sagittarius, Ophiuchus, and Scorpius meet. Sagittarius boasts more Messier objects than any other constellation—it has 15 in all.

Although old star charts depicted this constellation as a centaur, in Greek mythology Sagittarius was identified as a different type of creature, known as a satyr. He is usually said to be Crotus, son of Pan, who invented archery and went hunting on horseback. He is seen aiming his bow at neighboring Scorpius.

Omega Nebula, M17. The loose cluster of stars within it can be detected through binoculars. M22 is one of the finest globular clusters in the entire sky. Under good conditions, it is visible to the naked eye. Through a small telescope, it is somewhat elliptical in outline, while one with an aperture of 3 in (75 mm) will resolve its brightest stars. M23 is a large open cluster visible through binoculars near the border with Ophiuchus. M25 is another binocular cluster, while M24 is a bright Milky Way star field the length of four diameters of a full moon.

SPECIFIC FEATURES Beta (β) Sagittarii appears to the naked eye as a pair of 4th-magnitude stars. The more northerly (and slightly brighter) of the two stars has a 7thmagnitude companion. All three stars are at different distances, and thus are unrelated. Probably the finest AQUARIUS object for binoculars is M8, the Lagoon Nebula CAPRICORNUS (see p.243), which extends for three times the width of a full moon. It contains the cluster NGC 6530, with stars of 7th magnitude and fainter, as well as the -20 6th-magnitude blue ˚ supergiant 9 Sagittarii. The Trifid Nebula, M20 (see p.246), is so named because it is trisected by dark lanes of dust. Visually, it is far -30 less impressive than its ˚ photographic representation, and little more than the faint double star at its center can be identified through a small instrument. On the northern border of Sagittarius with Scutum -40 ˚ lies another frequently photographed object—the

20h

This prominent globular cluster lies near the lid of the Teapot. Through binoculars, it appears as a woolly ball about two-thirds the apparent diameter of a full moon. 19h

18h

OPHIUCHUS

NGC 6818

56

60

ω

62

π ο

IC

ξ1,21,2 ν

ψ

52

M22

SAGITTARIUS

θ1

λ

M20

M28

4 M8

X W

M69

ε

δ

γ

Sgr A*

Kaus Australis

η

NGC 6723

SCORPIUS Shaula

ι

α

CORONA AUSTRALIS

β1

β2

TELESCOPIUM

INDUS -50

M21

11

TEAPOT

M70

M23

μ

ϕ

MILK DIPPER M54

M55

M24

21

Nunki

τ ζσ

59 RR

M17 M18 M25 Y

NGC 6716

43

ECLIPT

M75

SERPENS CAUDA

SCUTUM

υ ρ1

NGC 6822

THE LAGOON NEBULA 154

One of the largest nebulae in the sky is M8, which appears in binoculars as an elongated, milky patch of light with embedded stars, including those in the cluster NGC 6530, which make it glow.

M22 15

ARA

˚

TH E N I G H T S KY

THE ARCHER

THE OMEGA NEBULA 154 THE TRIFID NEBULA 54

The pinkish emission of the Trifid Nebula contrasts with the blue reflection nebula to its north, as revealed on long-exposure photographs and CCD images. At its heart is a faint double star, which is overexposed on this image.

M17 can be glimpsed through binoculars but shows up better through a telescope. It resembles the Greek capital letter omega (Ω). However, others see it as a swan, hence its alternative name, the Swan Nebula.

401

MOUNTED BOWMAN 2

The stars that make up the outline of Sagittarius, the Archer, lie in front of dense Milky Way star fields toward the center of our Galaxy. North is to the left in this photograph.

T HE N I G H T S K Y

402

THE CONSTELLATIONS THE SCORPION

Scorpius SIZE RANKING

33

BRIGHTEST STAR

Antares (α) 1.0 (variable) ABBREVIATION GENITIVE

Sco

Scorpii

HIGHEST IN SKY AT 10 PM

June–July FULLY VISIBLE

44°N–90°S

This beautiful and easily recognizable zodiacal constellation is situated in the southern sky. It depicts a scorpion (see panel, below) whose raised tail is marked by a curve of stars extending into a rich area of the Milky Way toward the center of the Galaxy.

SPECIFIC FEATURES Antares, or Alpha (α) Scorpii (see p.256), is a red supergiant hundreds of times larger than the Sun. It fluctuates from about magnitude 0.9 to 1.2 every four to five years. Normally, Delta (δ) Scorpii is of magnitude 2.3, but in the year 2000 it unexpectedly began to brighten by over 50 percent. Whether it will remain at its new magnitude or return to its previous value is unknown. Beta (β) Scorpii is a line-of-sight pair with components of 3rd and 5th magnitudes, while Omega (ω) Scorpii is an even wider unrelated pair, with stars of 4th magnitude. A small telescope easily splits Nu (ν) Scorpii into a double with components of 4th and 6th magnitudes. Mu (μ) Scorpii is another naked-eye pair, with stars of 3rd and 4th magnitudes. More complex is Xi (ξ) Scorpii, a white and orange pair of stars of 4th and 7th magnitudes. In the same field of view a fainter and wider pair

can also be seen. All four stars are gravitationally linked, making this a genuine quadruple. The open cluster M7 is visible to the naked eye as a hazy patch. It has dozens of stars of 6th magnitude and fainter scattered over an area twice the apparent width of a full moon. About twice as distant is M6, which is known as the Butterfly Cluster (see p.290) because of its shape when viewed through binoculars. On one wing lies BM Scorpii, a variable orange giant. Near Antares, M4 (see p.294) is one of the closest globular clusters to us, at 7,000 light-years away. Just too far south to have featured on Charles Messier’s list (see p.73) is the open cluster NGC 6231. Its brightest member, 5th-magnitude Zeta (ζ) Scorpii, has a 4th-magnitude companion much closer to us. The strongest X-ray source in the sky is Scorpius X-1. This consists of a 13th-magnitude blue star orbited by a neutron star.

GLITTERING CLUSTERS 21

Two prominent star clusters, M6 and M7, adorn the tail of Scorpius in the Milky Way. M6 is at the center of this photograph; M7 is bottom left. THE SCORPION

-10°

Sco X-1

SERPENS CAUDA

-20°

OPHIUCHUS ECLIPTIC

M80

2

22

SAGITTARIUS

Antares

M4

1

LIBRA

13 M6

RR

SCORPIUS

LUPUS

NGC 6383

M7

Shaula

-40°

NGC 6322

NGC 6388

NGC 6124 NGC 6231 NGC 6178

NORMA TELESCOPIUM -50°

ARA 18h

17h

MYTHS AND STORIES

TH E N I G H T S KY

THE DEATH OF ORION In Greek mythology, Scorpius was the scorpion that stung Orion to death. According to one story, the scorpion was sent by Artemis, the goddess of hunting, after Orion had tried to attack her, while another account relates how Mother Earth dispatched the scorpion to humble Orion after he had boasted that he could kill any wild beast. STING IN THE TAIL 2

This view of Scorpius has south at the top and shows the scorpion raising its curving tail as though to strike. Its heart is marked by the red star Antares.

MISPLACED FOOT

Like other old star charts, Jean Fortin’s Atlas Céleste shows the foot of Ophiuchus awkwardly overlapping Scorpius.

16h

22h

M30 15

THE SEA GOAT

Capricornus SIZE RANKING

40

BRIGHTEST STAR

Deneb

Algedi (δ) 2.9 GENITIVE

Capricorni

ABBREVIATION

Chains of stars extending like fingers from the northern side of this cluster are visible through a large telescope.

403

AQUARIUS -10° Algedi Deneb Algedi

-20°

Cap

HIGHEST IN SKY AT 10 PM

20h

21h

CAPRICORNUS

36

THE SEA GOAT

August–September

ECLI

M30

PTIC

24

FULLY VISIBLE

62°N–90°S -30°

PISCIS AUSTRINUS

SAGITTARIUS MICROSCOPIUM

This is the smallest constellation of the zodiac and not at all prominent; it is situated in the southern sky between Sagittarius and Aquarius. In Greek myth, Capricornus represents the goatlike god Pan (see panel, right), who jumped into a river and became part fish to escape from the monster Typhon. SPECIFIC FEATURES Alpha (α) Capricorni is a wide pairing of unrelated 4th-magnitude stars. They can be separated through binoculars or even with good eyesight. Alpha-1 (α1) Capricorni is a yellow supergiant nearly 700 lightyears away, while Alpha-2 (α2) is a yellow giant less than one-sixth that distance from Earth. Beta (β) Capricorni is a 3rdmagnitude yellow giant with a 6thmagnitude blue-white companion that can be seen through a small telescope or even good binoculars. The modest globular cluster M30 is visible as a hazy patch through a small telescope.

MYTHS AND STORIES

PAN This Greek god of the countryside had the hind legs and horns of a male goat but the body of a human. He created the pipes of Pan, also known as the syrinx, from reeds of different lengths. PAN-PIPER

This stone statue of Pan playing his reed pipes is to be found in the garden of a castle in Schwetzingen, Germany.

CAPRICORNUS AND MARS 2

Mars is here seen here to the left of Capricornus, whose stars form a roughly triangular shape depicting Pan as half goat, half fish.

THE MICROSCOPE

CAPRICORNUS

SIZE RANKING

66

BRIGHTEST STARS

Gamma (γ) 4.7, Epsilon (ε) 4.7 GENITIVE

21h

22h

Microscopium

SAGITTARIUS PISCIS AUSTRINUS MICROSCOPIUM -30°

Microscopii

ABBREVIATION

Mic

HIGHEST IN SKY AT 10 PM

August–September

GRUS

FULLY VISIBLE

45°N–90°S

SPECIFIC FEATURES The orange giant Alpha (α) Microscopii, of 5th magnitude, has a 10th-magnitude companion that is visible through an amateur telescope.

INDUS -50°

THE MICROSCOPE

UNDER THE MICROSCOPE 2

Microscopium is a faint and almost featureless constellation. It lies near Capricornus and the much more conspicuous Sagittarius.

T HE N I G H T S KY

Microscopium is a faint and obscure southern constellation to be found between Sagittarius and Piscis Austrinus. It was invented in the 18th century by the French astronomer Nicolas Louis de Lacaille (see p.422), and it represents an early design of compound microscope.

404

THE CONSTELLATIONS THE SOUTHERN FISH

Piscis Austrinus SIZE RANKING

60

BRIGHTEST STAR

Fomalhaut (α) 1.2 GENITIVE

22h

23h

Piscis

Austrini ABBREVIATION

AQUARIUS

SPECIFIC FEATURES Beta (β) Piscis Austrini is a wide double star with components of 4th and 8th magnitudes. It is divisible through a small telescope. More difficult to separate with a small telescope is Gamma (γ) Piscis Austrini, a closer pair of stars of 5th and 8th magnitudes.

CAPRICORNUS PISCIS AUSTRINUS -30° Fomalhaut

PsA

HIGHEST IN SKY AT 10 PM

September–October

THE SOUTHERN FISH

GRUS -40°

FULLY VISIBLE

53°N–90°S

Piscis Austrinus was known to the ancient Greeks, including Ptolemy in the 2nd century ad. It depicts a fish, which was said to be the parent of the two fish represented by the zodiacal constellation Pisces. This constellation has also been called Piscis Australis. It is made prominent in the Southern Hemisphere by the presence of 1stmagnitude Fomalhaut, or Alpha (α) Piscis Austrini (see p.253). This bluewhite star lies 25 light-years away. NEVER-ENDING DRINK 2

In the sky, water from the jar of the adjacent Aquarius, the Water Carrier, flows toward the mouth of the fish, marked by Fomalhaut. The star’s name is an Arabic term meaning “fish’s mouth.”

THE SCULPTOR

Sculptor SIZE RANKING

36

BRIGHTEST STAR

Alpha (α) 4.3 GENITIVE

Sculptoris

ABBREVIATION

Scl

HIGHEST IN SKY AT 10 PM

October–November

The spiral galaxy NGC 253 is seen nearly edge-on, so that it appears highly elongated. Under good sky conditions, it can be picked up through binoculars or a small telescope. Nearby lies the fainter and smaller globular cluster NGC 288. Another spiral galaxy is NGC 55, which is similar in size and shape to NGC 253.

0h

1h

2h

CETUS

23h

AQUARIUS NGC 253 NGC 288

-30°

FORNAX

Fomalhaut

S

R

NGC 7793

FULLY VISIBLE

SCULPTOR

50°N–90°S

NGC 55

TH E N I G H T S KY

-40°

This unremarkable southern constellation was introduced in the 18th century by the French astronomer Nicolas Louis de Lacaille (see p.422). He originally described it as representing a sculptor’s studio, although the name has since been shortened. Sculptor contains the south pole of our galaxy—that is, the point 90 degrees south of the plane of the Milky Way. As a result, we can see numerous far-off galaxies in this direction, since they are unobscured by intervening stars or nebulae. SPECIFIC FEATURES Epsilon (ε) Sculptoris is a binary star that can be separated with a small telescope. Its components, of 5th and 9th magnitudes, have an orbital period of more than 1,000 years.

PISCIS AUSTRINUS

PHOENIX

NGC 55 54

THE SCULPTOR

BRIGHT NEIGHBOR 2

The faint constellation of Sculptor is outshone by Fomalhaut, the leading star of adjoining Piscis Austrinus, seen below Sculptor in this image.

This patchy-looking spiral galaxy, seen nearly edge-on, is mottled with dust clouds and areas of star formation.

THE CONSTELLATIONS chemists for distillation. It was originally known by the name Fornax Chemica, the chemical furnace, but this has since been shortened to Fornax.

THE FURNACE

Fornax SIZE RANKING

41

BRIGHTEST STAR

Alpha

(α) 3.9 GENITIVE

Fornacis

ABBREVIATION

For

HIGHEST IN SKY AT 10 PM

November–December FULLY VISIBLE

50°N–90°S

A handful of faint stars makes up this undistinguished constellation of the southern sky. Fornax is situated on the edge of Eridanus and Cetus, and it represents a furnace used by

405

NGC 1365 534

This barred spiral galaxy is the largest in the Fornax Cluster and is about as massive as the Milky Way. It can be identified through a moderate-sized telescope.

SPECIFIC FEATURES The brightest star in the constellation, 4th-magnitude Alpha (α) Fornacis, has a yellow companion, which orbits it every 300 years. This 7thmagnitude star is visible through a small telescope. On the border of Fornax with Eridanus lies a small cluster of galaxies known as the Fornax Cluster (see p.329). It is about 65 million lightyears away, and its brightest member— the peculiar spiral NGC 1316—is a radio source known as Fornax A. Another prominent member of the Fornax Cluster is the beautiful barred spiral galaxy NGC 1365.

THE FORNAX CLUSTER 534

Most of the galaxies in this cluster in southern Fornax are ellipticals, including the 10th-magnitude NGC 1399 (left of center in this photograph). Standing out among the elliptical galaxies is the large barred spiral NGC 1365 (bottom right).

THE FURNACE

3h

4h

2h

-20°

CETUS FORNAX -30°

NGC 1365 NGC 1316

-40°

ERIDANUS

PROTECTED POSITION 2

Fornax is tucked into a bend in the celestial river, Eridanus. It was introduced by Nicolas Louis de Lacaille during the 18th century.

PHOENIX HOROLOGIUM

5h

THE CHISEL

Caelum

4h

THE CHISEL

LEPUS SIZE RANKING

81

BRIGHTEST STAR

Alpha

(α) 4.4 ABBREVIATION GENITIVE

ERIDANUS

-30°

Cae

Caeli

HIGHEST IN SKY AT 10 PM

December–January FULLY VISIBLE

41°N–90°S

-40°

CAELUM

SPECIFIC FEATURES Gamma (γ) Caeli is a double star, consisting of an orange giant of magnitude 4.6, with an

-50°

HOROLOGIUM DORADO

8th-magnitude companion. Because they are positioned close together, a modest-sized telescope is required in order to separate them.

ENGRAVED IN STONE 2

Beta (β) and Alpha (α) Caeli mark the shaft of the celestial chisel, which points toward the constellations Dorado and Reticulum in the south.

T HE N I G H T S K Y

Sandwiched between Eridanus and Columba is this small and faint southern constellation, which was introduced in the 18th century by the French astronomer Nicolas Louis de Lacaille (see p.422). It represents a stonemason’s chisel.

406

THE CONSTELLATIONS The galaxy NGC 1300 is estimated to lie around 75 million light-years away and is too faint for viewing through a small telescope. However, it shows up beautifully on photographs.

and fell into the river below. This river has been identified with two real ones: the Nile in Egypt and the Po in Italy.

THE RIVER

Eridanus SIZE RANKING

6

BRIGHTEST STAR

Achernar (α) 0.5 GENITIVE

Eridani

ABBREVIATION

Eri

HIGHEST IN SKY AT 10 PM

November–January FULLY VISIBLE

32°N–89°S

This large constellation represents a river meandering from the foot of Taurus south to Hydrus. Its range in declination of 58 degrees is the greatest of any constellation. The only star of any note in Eridanus is 1st-magnitude Achernar, or Alpha (α) Eridani, which lies at the southern tip of the constellation. The name Achernar is of Arabic origin and means “river’s end.” Eridanus features in the story of Phaethon, son of the sun god Helios, who attempted to drive his father’s chariot across the sky. He lost control

SPECIFIC FEATURES For all its size, Eridanus is short on objects of interest for a small MULTIPLE STAR telescope. The best is the multiple star The primary star of Omicron-2 (ο2) Eridani Omicron-2 (ο2) Eridani (see p.276), is in the center of this photograph, while its also known as 40 Eridani, which white-dwarf and red-dwarf companions includes both a red dwarf and a white overlap each other to the right. one. To the eye, it appears as a 4th-magnitude orange 4h ORION 5h star, but a small telescope reveals a 10th-magnitude companion, the white dwarf. This is the easiest 45 white dwarf to spot with a 32 small telescope. It forms a binary with a fainter red 17 dwarf, although this star may require a telescope with a slightly larger aperture to be detectable. 39 Two double stars of 64 note are Theta (θ) Eridani, NGC 1535 consisting of white stars of 53 LEPUS 3rd and 4th magnitudes ERIDANUS divisible through a small telescope, and 32 Eridani, a NGC 1300 54 contrasting pair of orange and blue stars of 5th and 6th 15 magnitudes, also within range of a small telescope.

3h

CETUS

FORNAX -30

˚

-40

˚ PHOENIX

CAELUM

HOROLOGIUM

Achernar

TH E N I G H T S KY

THE RIVER

NGC 1300 54 CELESTIAL RIVER 2

Eridanus has its source next to Rigel (in Orion) and flows south to Achernar. It is fully visible to almost all of the Southern Hemisphere and half of the Northern.

This is a classic example of a barred spiral galaxy. The length of its central bar is greater than the diameter of the Milky Way, being 150,000 light-years across.

407

ORION THE HARE

Lepus SIZE RANKING

51 Arneb

BRIGHTEST STAR

(α) 2.6 GENITIVE

Leporis

ABBREVIATION

Lep

HIGHEST IN SKY AT 10 PM

January FULLY VISIBLE

62°N–90°S

Lepus is often overlooked because it is surrounded by sparkling Orion and Canis Major, yet it is worthy of note. It is one of the constellations known to the ancient Greeks.

SPECIFIC FEATURES Gamma (γ) Leporis is a 4th-magnitude yellow star with a 6th-magnitude orange companion, which is visible through binoculars. Another double star is Kappa (κ) Leporis, a 4th-magnitude star with a close companion of 7th magnitude. It is difficult to separate through telescopes of small aperture. NGC 2017 is a compact group of stars in what seems to be a chance alignment. Thus it is not a true star cluster at all. Near the border with Eridanus lies R Leporis, an intensely red variable star of the same type as Mira (in Cetus). Its brightness ranges from 6th to 12th magnitude every 14 months or so. The globular cluster M79 can be seen though a small telescope. In the same field of view lies Herschel 3752, a triple star with components of 5th, 7th, and 9th magnitudes.

MONOCEROS

Rigel

˚

RX

Sirius

R

17

ERIDANUS

NGC 2017

Arneb -20

˚

Nihal

CANIS MAJOR

LEPUS

M79

Adhara -30

6h

M79 15

This somewhat sparse 8th-magnitude globular cluster, 42,000 light-years away, has long starry arms that give it the appearance of a starfish.

-10

THE HARE

COLUMBA

˚

CAELUM 5h

NGC 2017 5

This open cluster consists of a 6th-magnitude star with four companions of 8th to 10th magnitude, which are visible through a small telescope. Larger apertures reveal three fainter stars in the group.

MYTHS AND STORIES

A RUNNING HARE According to Greek mythology, there were no hares on the island of Leros until one man introduced a pregnant female. Soon everyone was raising hares, but they became pests, destroying crops and reducing the population to starvation. The inhabitants eventually drove the hares out of the island and put the image of the hare among the stars as a reminder that one can have too much of a good thing. THE HUNTER AND HUNTED

SAFE HAVEN 2

Lepus, the celestial hare, crouches under the feet of Orion, like an animal trying to hide from its hunter. Orion’s dogs, Canis Major and Canis Minor, lie nearby.

T HE N I G H T S K Y

One of Orion’s dogs chases the hare in this 15th-century Flemish illustration, which was based on the Liber Floridus of Lambertus, compiled during the Middle Ages.

408

THE CONSTELLATIONS

6h

7h

5h

Adhara

THE DOVE -30°

Columba

CANIS MAJOR

μ COLUMBA Phact

SIZE RANKING

54

CAELUM

BRIGHTEST STAR

Phact (α) 2.7 GENITIVE

Columbae

ABBREVIATION

Col

-40°

NGC 1851

HIGHEST IN SKY AT 10 PM

January

PUPPIS

FULLY VISIBLE

46°N–90°S

BIRD WITH A MISSION 2

The Dutch theologian and astronomer Petrus Plancius (see p.358) formed this southern constellation in the late 16th century from stars near Lepus and Canis Major that had not previously been allocated to any constellation. It supposedly represents Noah’s dove (see panel, right). SPECIFIC FEATURES Fifth-magnitude Mu (μ) Columbae is a fast-moving star apparently thrown out from the area of the Orion Nebula about 2.5 million years ago. Astronomers think that it was once a member of a binary system that was disrupted by a close encounter with another star. The other member of the former binary, moving away from Orion in the opposite direction, is 6th-magnitude AE Aurigae. NGC 1851 is a modest globular cluster that is visible as a faint patch through a small telescope.

THE DOVE

In this image, north is to the left and the stars of Puppis and Canis Major lie beneath Columba, the Dove, which flies through the southern sky.

MYTHS AND STORIES

NOAH’S DOVE In the Biblical story of the Flood, Noah loaded an ark with a male and female of every kind of animal on Earth. It then rained for 40 days and 40 nights, drowning everything except the animals aboard the ark. When the rain abated, Noah sent out a dove to find dry land. The dove came back with an olive stem in its beak—a sure sign that the waters were at last receding. WINGED MESSENGER

The dove returns to Noah’s Ark, carrying an olive branch, in this illustration by a 10thcentury Catalan monk called Emeterio.

THE COMPASS 9h

Pyxis

8h

HYDRA SIZE RANKING

65

BRIGHTEST STAR

Alpha (α) 3.7 GENITIVE

-20°

Pyxidis

ABBREVIATION

PYXIS

Pyx

HIGHEST IN SKY AT 10 PM

February–March FULLY VISIBLE

52°N–90°S

-30°

T

TH E N I G H T S KY

ANTLIA

Pyxis is a faint and unremarkable southern constellation lying next to Puppis on the edge of the Milky Way. It represents a ship’s magnetic compass. The constellation was introduced in the 18th century by the French astronomer Nicolas Louis de Lacaille (see p.422). SPECIFIC FEATURES T Pyxidis is a recurrent nova—that is, one that has undergone several recorded outbursts. Five eruptions have been seen since 1890, the last being in 1966. During these outbursts, it has brightened to 6th or 7th magnitude. It is likely to brighten again at any time and become visible through binoculars.

PUPPIS

-40°

VELA THE COMPASS

COMPASS BEARINGS 2

In this image of the scattered stars of Pyxis, the Compass, north is on the left, and the stars of adjacent Puppis are to be found above Pyxis.

THE CONSTELLATIONS THE STERN

Puppis SIZE RANKING

20

BRIGHTEST STAR

Naos (ζ) 2.2 GENITIVE

Puppis

ABBREVIATION

Pup

HIGHEST IN SKY AT 10 PM

January–February FULLY VISIBLE

39°N–90°S

This rich southern constellation straddling the Milky Way was originally part of the ancient Greek constellation of Argo Navis (the ship of Jason and the Argonauts, see p.410) until it was divided into three parts in

the 18th century. Puppis, representing the ship’s stern, is the largest part. The stars of each section retained their original Greek letters, and in the case of Puppis the lettering now starts at Zeta (ζ) Puppis, a star that is also known as Naos. SPECIFIC FEATURES Third-magnitude Xi (ξ) Puppis has a wide and unrelated 5th-magnitude companion that is visible through binoculars, while k Puppis consists of a pair of nearly identical stars with components of 5th magnitude that can be split through a small telescope. L Puppis is a wide naked-eye and binocular pair, of which L2 Puppis is a variable red giant that ranges between 3rd and 6th magnitudes every five months or so. M46 and M47 are a pair of open clusters that together create a brighter patch in the Milky Way. Both appear NGC 2477 15

409

NGC 2477 is an open cluster that looks almost like a globular cluster when seen through binoculars, while NGC 2451 is more scattered and has the 4th-magnitude orange giant c Puppis near its center.

of similar size to a full moon. M46 is the richer of the two, while M47 is the closer, being about 1,500 lightyears away—that is, less than onethird of the distance of its apparent neighbor. The cluster M93 lies about 3,500 light-years away.

7h

9h

MONOCEROS

-10°

19

M47

Sirius

20

M46

CANIS MAJOR

16

-20°

11 M93

PYXIS

THE STERN

1

NGC 2571

Adhara

3

6h

-30°

k

This is one of the richest open clusters, containing an estimated 2,000 stars. It is about 4,000 light-years away. The star below NGC-2477 in this picture—b Puppis—is of magnitude 4.5.

NGC 2439

NGC 2451

c NGC 2546

COLUMBA

NGC 2477

b

-40° Naos

PUPPIS L2 L1

VELA

V

PICTOR

-50°

CARINA

Canopus

SHARP CLUSTER 15

STERN OF THE ARGO 2

The stars of Puppis, representing the stern of the Argo, are seen here rising behind thin clouds. Sirius (in Canis Major) lies near the left edge of this picture.

M46 AND NEBULA 15

A small planetary nebula, seen here below center, seems to be part of M46 but in fact lies in the foreground.

T HE N I G H T S K Y

M93 is an attractive open cluster for viewing through binoculars or a small telescope. It is shaped like an arrowhead with two orange giants near its tip.

410

THE CONSTELLATIONS THE SAILS

Vela

UNDER SAIL 2 SIZE RANKING

Vela represents the mainsail of the Argo, the ship of Jason and the Argonauts, sailing through the southern sky in the quest for the golden fleece.

32

BRIGHTEST STAR

Gamma (γ) 1.8 GENITIVE

Velorum

ABBREVIATION

Vel

HIGHEST IN SKY AT 10 PM

February–April FULLY VISIBLE

32°N–90°S

In the 18th century, the ancient Greek constellation Argo Navis (the ship of Jason and the Argonauts—see panel, below) was divided into three parts, one of which was Vela, which represents the ship’s sails. Because the stars labeled Alpha (α) and Beta (β) in the former Argo Navis are now in Carina, to the south, the labeling of the stars in Vela starts with Gamma (γ) Velorum, or Regor (see p.253). Between Gamma and Lambda (λ) Velorum are found the gaseous strands of the Vela supernova remnant (see p.269)—the supernova could have been seen from Earth around 11,000 years ago—while Delta (δ) and Kappa (κ) Velorum combine with two stars in Carina to form the False Cross (sometimes mistaken for the true Southern Cross).

THE EIGHT-BURST NEBULA 54

The planetary nebula NGC 3132 has loops of gas that interlock like figure-eights, hence the object’s popular name.

wider companions, with components of 8th and 9th magnitudes, are visible through a telescope. IC 2391 is the best star cluster in Vela for the naked eye or binoculars. It is a group of several dozen stars covering a greater area than a full moon. To the north of it is another binocular cluster, IC 2395. NGC 2547 is an open cluster half the size of a full moon and can be identified through binoculars or a small telescope. Popularly known as the EightBurst Nebula, NGC 3132 has complex loops that are revealed only through a large telescope or on longexposure photographs. A small telescope will show the nebula’s disk, of similar apparent size to Jupiter, and the 10th-magnitude star at its center.

SPECIFIC FEATURES Gamma Velorum is the brightest example of a Wolf–Rayet star, a rare type of star that has lost its outer layers, thereby exposing its ultra-hot interior. A 4th-magnitude companion is visible through a small telescope or good binoculars. In addition, two

THE SAILS

MYTHS AND STORIES

THE ARGONAUTS The Argo was a mighty 50-oared galley in which Jason and 50 of the greatest Greek heroes, called the Argonauts, sailed to Colchis, on the eastern shore of the Black Sea, on their mission to find the golden fleece of a ram. Their epic voyage is one of the great stories of Greek myth.

ANTLIA

ψ

NGC 3132

λ

-40

PUPPIS

VELA

NGC 3201

γ

LEGENDARY SAILING GALLEY

μ

The Argo, ship of the Argonauts, is here depicted by the Italian artist Lorenzo Costa (1459–1535).

IC 2395 NGC 3228

ϕ

CENTAURUS

TH E N I G H T S KY

PYXIS

κ

IC 2391

ο

NGC 2547

-50

˚

δ

IC 2488

8h 9h

CARINA

IC 2391 21 11h

10h

Omicron (ο) Velorum, at magnitude 3.6, is the brightest member of IC 2391, a scattered cluster that lies some 500 light-years from Earth in the southern reaches of Vela.

˚

9h

411

7h 10h

PUPPIS

THE KEEL

χ

VELA

Carina SIZE RANKING

34

α

THE KEEL NGC 3293

BRIGHTEST STAR

Canopus (α) -0.6 GENITIVE

NGC 3532

Carinae

ABBREVIATION

Car

η NGC 3372

Gacrux

IC 2581

ε

CARINA

Canopus

NGC 2516

l

S

υ

θ

CRUX

ι

NGC 3114

IC 2602

HIGHEST IN SKY AT 10 PM

January–April FULLY VISIBLE

6h

PICTOR

R NGC 2808

VOLANS

β

DORADO

14°N–90°S

ω

Acrux

Carina is a major southern constellation that was originally part of the larger figure of Argo Navis, which depicted a ship, until that was split up in the 18th century. Carina represents the ship’s keel. Its most prominent star, Canopus, or Alpha (α) Carinae, is a white supergiant 310 light-years away and second in brightness only to Sirius in the entire sky. The stars Epsilon (ε) and Iota (ι) Carinae form a pseudo “southern cross,” known as the False Cross, in conjunction with two stars in neighboring Vela. SPECIFIC FEATURES Splashed across the Milky Way near the border with Centaurus and Vela is the Carina Nebula, NGC 3372 (see p.247), a patch of glowing gas four diameters of a full moon wide. It is visible to the eye and well seen through binoculars. The densest and brightest part of the nebula is around Eta (η) Carinae (see p.262), an

unusual variable star that flared up during the 19th century to become temporarily the second-brightest star in the sky, although it has now subsided to around 5th magnitude. A shell of gas around Eta, which was thrown off during the outburst, is visible through a telescope, next to the Keyhole Nebula, which appears as a dark and bulbous cloud of dust silhouetted against the glowing gas of the Carina Nebula. A glorious sight through binoculars, another treasure is IC 2602, an open cluster known as the Southern Pleiades. Twice the apparent size of a full moon, it contains several stars visible to the naked eye—the brightest being 3rdmagnitude Theta (θ) Carinae. Among Carina’s naked-eye clusters is NGC 3532. At its widest point, this elongated group of stars is twice the width of a full moon. NGC 3114 is about the same apparent size as a full moon, its brightest individual members being visible through binoculars. NGC 2516 is sparser and appears cross-shaped through binoculars. Its brightest star is a 5th-magnitude red giant.

MUSCA -70

˚ CHAMAELEON -80

˚

ELONGATED CLUSTER 1

What appears to be the brightest member of NGC 3532, in the lower left of this photograph, is in fact an extremely luminous background star some four times farther off. THE CARINA NEBULA 215

The brightest part of this immense cloud of glowing gas is V-shaped (shown here), while the star Eta (η) Carinae itself (below left of center) is a peculiar variable that appears as a hazy orange ellipse.

Carina represents the keel and hull of the Argonauts’ ship, the Argo. The blade of the steering oar is marked by Canopus, Carina’s brightest star.

T HE N I G H T S K Y

EVEN KEEL 2

412

THE CONSTELLATIONS THE SOUTHERN CROSS

Crux SIZE RANKING

88

Acrux (α) 0.8, Becrux (or Mimosa) (β) 1.3 BRIGHTEST STARS

GENITIVE

Crucis

ABBREVIATION

Cru

HIGHEST IN SKY AT 10 PM

April–May

supergiant that contrasts with the blue-white sparkle of the other stars, producing a resemblance to a casket of jewels, hence the popular name. The Coalsack Nebula is to be found beside the Jewel Box. This dark cloud of dust blocks light from the stars of the Milky Way behind it. It spans the width of 12 full moons and extends into neighboring Centaurus and Musca, so it is prominent to the naked eye and through binoculars.

VELA -50

˚ CENTAURUS

-60

˚

μ γ CRUX δ λβ ε NGC ι 4755 Coal- α θ1,2 sack Acrux ζ CARINA η

Hadar

THE SOUTHERN CROSS

FULLY VISIBLE

MUSCA

25°N–90°S -70

˚ 14h

13h

12h

11h

Crux lies in a rich area of the Milky Way. Although it is the smallest constellation, it is instantly recognizable and is squeezed between the legs of the centaur, Centaurus. The longer axis of the Southern Cross, as Crux is popularly known, points toward the south celestial pole. Its stars were known to the ancient Greeks (see panel, below), who regarded them as part of Centaurus. They were made into a separate constellation in the 16th century. SPECIFIC FEATURES Alpha (α) Crucis or Acrux is the most southerly first-magnitude star. It is a glittering double that is readily divisible through a small telescope. The two components are of magnitudes 1.3 and 1.8. A wider 5thmagnitude star can be seen through binoculars; it is not related to Acrux. The star at the top of the cross is the 2nd-magnitude red giant Gamma (γ) Crucis or Gacrux. It has an unrelated 6th-magnitude companion visible through binoculars. Nearby, Mu (μ) Crucis is a wide pair of 4th- and 5th-magnitude stars easily separated through a small telescope or even good binoculars. One of the gems of the southern sky is the Jewel Box Cluster (see p.294), or NGC 4755, visible to the naked eye as a brighter patch within the Milky Way near Beta (β) Crucis or Becrux. Its individual stars, the brightest being of 6th magnitude, cover about one-third the width of a full moon. They can be viewed through binoculars or a small telescope. Near the center is a ruby-colored

SIGN OF THE CROSS 2

Four prominent stars make up the Southern Cross, one of the most famous of all celestial patterns, which appears on the flags of several nations.

EXPLORING SPACE

REDISCOVERING STARS

T HE N I G H T S KY

THE COALSACK 21

The Coalsack Nebula, which lies next to the stars of the Southern Cross, is a smudgy cloud of interstellar dust silhouetted against the bright background of the Milky Way. JEWELS OF THE SKIES 15

The Jewel Box Cluster is a sparkling group of stars just north of the Coalsack Nebula, although the cluster is almost ten times more distant from Earth.

When European seafarers returned from exploring the southern latitudes in the 15th and 16th centuries, they reported stars they had never seen before. Among these explorers was Amerigo Vespucci (14541512), an Italian who in 1501 charted Alpha (α) and Beta (β) Centauri and the stars of Crux. Astronomers later realized that these stars had been known to the ancient Greeks but that precession (see p.64) had subsequently carried them below the horizon in Europe. AMERIGO VESPUCCI

This imaginative view of Amerigo Vespucci observing the Southern Cross with an astrolabe was painted by the 16th-century Flemish artist Joannes Stradanus (Hans van der Straet).

THE CONSTELLATIONS

413

THE FLY

Musca SIZE RANKING

77

BRIGHTEST STAR

Alpha (α) 2.7 GENITIVE

Muscae

ABBREVIATION

Mus

HIGHEST IN SKY AT 10 PM

April–May

NGC 4833 15

This globular cluster is just visible through binoculars. Individual stars can be resolved with a telescope of 4-in (100 mm) aperture.

FULLY VISIBLE

14°N–90°S

This modest constellation is to be found in the Milky Way south of Crux and Centaurus. In fact, the southern tip of the dark Coalsack Nebula extends into it from Crux. Musca is one of the southern constellations introduced at the end of the 16th century by the Dutch navigator-astronomers Pieter Dirkszoon Keyser and Frederick de Houtman. It represents a fly. SPECIFIC FEATURES Theta (θ) Muscae is a double star with components of 6th and 8th magnitude, divisible through a small telescope. The fainter component is an example of a Wolf–Rayet star—a hot star that has lost its outer layers. Musca also has a globular cluster, known as NGC 4833 (see p.295).

CRUX Hadar Acrux

CENTAURUS -60°

Rigil Kentaurus

CIRCINUS

θ η NGC 4833

δ -70°

β

ε α

μ

λ

CARINA

γ

MUSCA FINDING THE FLY 2

CHAMAELEON

The long axis of the Southern Cross points to Musca, the fly, which lies on the edge of the Milky Way within the southern celestial hemisphere.

APUS 14h 13h

12h

THE FLY

THE COMPASS

CENTAURUS

Circinus SIZE RANKING

85

BRIGHTEST STAR

-50

˚

LUPUS

NORMA

Alpha (α) 3.2 GENITIVE

Circini

ABBREVIATION

γ β

Cir

Hadar

HIGHEST IN SKY AT 10 PM

May–June FULLY VISIBLE

-60

˚

ε

Rigil Kentaurus

CRUX

α

19°N–90°S

CIRCINUS

SPECIFIC FEATURES Circinus contains little of interest for amateur astronomers. Alpha (α) Circini, however, is its one star of note. It is situated against the background of the Milky Way and is easy to identify, being a double with components of 3rd and 9th magnitudes. These are divisible through a small telescope.

TRIANGULUM AUSTRALE 16h

15h

MUSCA 14h

THE COMPASS

GEOMETRIC SHAPE 2

Circinus forms a slim triangle of stars and is squashed into a sliver of the southern sky next to the brilliant Alpha (α) and Beta (β) Centauri.

T HE N I G H T S K Y

Circinus represents a dividing compass, as used by surveyors and navigators. It is one of the figures introduced in the 18th century by the French astronomer Nicolas Louis de Lacaille (see p.422). This small southern constellation is squeezed awkwardly in between Centaurus and Triangulum Australe. It lies next to Alpha (α) Centauri, so it is not difficult to locate.

414

THE CONSTELLATIONS THE SET SQUARE

Norma SIZE RANKING

74

BRIGHTEST STAR

Gamma-2 (γ2) 4.0 GENITIVE

Normae

ABBREVIATION

Nor

HIGHEST IN SKY AT 10 PM

June FULLY VISIBLE

29°N–90°S

NGC 6067 15

Norma was introduced in the 1750s by the Frenchman Nicolas Louis de Lacaille (see p.422), and was originally known as Norma et Regula, the square and ruler. It is an unremarkable southern constellation lying in the Milky Way between Lupus and the zodiacal constellation of Scorpius. The stars that Lacaille designated Alpha (α) and Beta (β) have since been incorporated into Scorpius. SPECIFIC FEATURES At magnitude 4.0, Gamma-2 (γ2) Normae is the constellation’s brightest star, and it is one-half of a naked-eye double together with Gamma-1 (γ1) Normae, of magnitude 5.0. The two stars lie at widely different distances and hence are unrelated. Two other doubles in the constellation that are readily separated through a small telescope are Epsilon (ε) Normae, with components of 5th and 7th magnitudes, and Iota-1 (ι1) Normae, with components of 5th and 8th magnitudes. NGC 6087 is a large open cluster that has radiating chains of stars, which are visible through binoculars. Near its center is its brightest star, S-Normae—a Cepheid variable that ranges in brightness from magnitude 6.1 to 6.8 every 9.8 days.

THE SOUTHERN TRIANGLE

Triangulum Australe SIZE RANKING

Alpha (α) 1.9 Trianguli

Australis ABBREVIATION

TrA

HIGHEST IN SKY AT 10 PM

June–July FULLY VISIBLE

TH E N I G H T S KY

19°N–90°S

Triangulum Australe is one of the constellations of the southern sky that was introduced at the end of the 16th century by the Dutch navigators Pieter Dirkszoon Keyser and Frederick de Houtman. It is the smallest of the 12 they identified.

16h

17h

SCORPIUS -40

˚ δ

μ ε -50

NGC 6167

˚

γ1

η

2

γ NORMA

LUPUS

NGC 6067

ARA

κ

1

ι2 ι

CENTAURUS

NGC 6087

-60

RIGHT ANGLE 2

˚

Norma’s most distinctive feature is a right-angled trio of three faint stars, which is somewhat difficult to identify among the rich Milky Way star fields.

Although smaller than its northern counterpart, Triangulum, this constellation contains brighter stars and so is more prominent. SPECIFIC FEATURES NGC 6025 lies on Triangulum Australe’s northern border with Norma. It is 2,700 light-years away from Earth. This open cluster is noticeably elongated in shape and is about one-third the apparent diameter of a full moon. It is easily seen through binoculars. Alpha (α) Trianguli Australis is an orange giant whose color shows prominently through binoculars. There is nothing else in the constellation to attract users of small telescopes.

CIRCINUS

THE SET SQUARE

SOUTHERN TRIPLET 2

Triangulum Australe is an easily recognized triangle of stars, lying in the Milky Way near brilliant Alpha (α) and Beta (β) Centauri, which here are visible on the right.

83

BRIGHTEST STAR

GENITIVE

This rich cluster covers an area of sky about half the apparent diameter of a full moon. It is seen against the backdrop of the Milky Way.

ARA

CENTAURUS NGC 6025

δ

-60°

PAVO

Rigil Hadar Kentaurus

ε

α

CIRCINUS

γ ζ

-70° 17h 18h

β

TRIANGULUM AUSTRALE 16h

15h 14h

THE SOUTHERN TRIANGLE

Rigil Kentaurus

Shaula

SCORPIUS

CORONA AUSTRALIS

THE ALTAR

Ara SIZE RANKING

63

BRIGHTEST STARS Alpha (α) 2.8, Beta (β) 2.8 GENITIVE

Arae

ABBREVIATION

θ -50

˚

TELESCOPIUM

σ λ α

NGC 6397

Ara

HIGHEST IN SKY AT 10 PM

June–July

415

NGC 6193 NGC 6352

1 ε2 ε β ζ γ

NORMA

η

FULLY VISIBLE

-60

22°N–90°S

˚

δ ARA 19h

Ara was visualized by the ancient Greeks as the altar on which the gods of Olympus swore an oath of allegiance before their battle with the Titans for control of the universe (see

TRIANGULUM AUSTRALE

NGC 6362

PAVO

18h

17h 16h

THE ALTAR

panel, left). This southern constellation lies within the Milky Way and is situated south of Scorpius.

MYTHS AND STORIES

TITANOMACHIA Titanomachia, or the Clash of the Titans, was the ten-year war for dominance of the universe between the gods on Mount Olympus, led by Zeus, and the Titans on Mount Othrys. In gratitude for their victory, Zeus placed the altar of the gods in the sky. VICTORY PANEL

Part of the battle of the gods and Titans is here depicted in the Zeus Altar of Pergamon, which was sculpted in Greece c. 180 BC.

SPECIFIC FEATURES The attractive open cluster NGC 6193 consists of about 30 stars of 6th magnitude and fainter. It can be viewed through binoculars. NGC 6397 is among the closest globular clusters to us, being around 10,000 light-years away, and can be seen well through binoculars or a small telescope. Like NGC 6193, it appears relatively large—both being over half the apparent width of a full moon. Ara contains no stars of particular interest to users of small telescopes. NGC 6397 15

The globular cluster NGC 6397 has a condensed center and scattered outer regions in which chains and sprays of stars can be traced.

THE SOUTHERN CROWN

Corona Australis SIZE RANKING

80

Alpha (α) 4.1, Beta (β) 4.1 BRIGHTEST STARS

GENITIVE

THE CONSTELLATIONS

Coronae

Australis ABBREVIATION

CrA

HIGHEST IN SKY AT 10 PM

July–August FULLY VISIBLE

The small southern constellation of Corona Australis lies under the feet of Sagittarius. It comprises stars of 4th magnitude and fainter, and it was one of the 48 constellations recognized by the ancient Greek astronomer Ptolemy (see p.347).

Ara, the celestial altar, is oriented with its top facing south. Incense burning on the altar might give off the “smoke” of the Milky Way above it.

THE NIGHT SKY

44°N–90°S

SPECIFIC FEATURES SOUTHERN ARC 2 Gamma (γ) Coronae Australis is a Corona Australis is an binary star with components of 5th attractive arc of stars magnitude. The pair orbit each other that represents a crown every 122 years, and they are slowly or laurel wreath. moving apart as seen from Earth. This means the components are becoming easier to view individually. Meanwhile, a 4-in (100-mm) aperture is -30° needed to divide this SAGITTARIUS challenging star. Kappa (κ) Coronae SCORPIUS Australis is an unrelated α γ ε κ CORONA double with components of Shaula β AUSTRALIS 6th magnitude, which are δ -40° θ readily divided through a ζ small telescope. NGC 6541 The modest globular cluster NGC 6541 covers about one-third the TELESCOPIUM apparent diameter of a full moon. It is 19h 18h visible through a small telescope THE SOUTHERN CROWN or binoculars.

INCENSE BURNER 2

416

THE CONSTELLATIONS were refractors with extremely long focal lengths—to reduce chromatic aberration—suspended from tall poles by ropes and pulleys.

THE TELESCOPE

Telescopium SIZE RANKING

57

BRIGHTEST STAR

Alpha (α) 3.5 GENITIVE

Telescopii

ABBREVIATION

Tel

HIGHEST IN SKY AT 10 PM

July–August FULLY VISIBLE

SPECIFIC FEATURES Delta (δ) Telescopii is an unrelated pair of stars with components of 5th-magnitude. It can be divided -40 ˚ with binoculars or even good eyesight.

LONG VIEW 2

Telescopium depicts an early design of refracting telescope with a long tube supported by a flimsy mounting—a far cry from the massive reflectors of today.

CORONA AUSTRALIS SAGITTARIUS

δ2δ1 α ε

MICROSCOPIUM

33°N–90°S

ι -50

Telescopium is an almost entirely undistinguished southern constellation near Sagittarius and Corona Australis. It was invented by the French astronomer Nicolas Louis de Lacaille (see p.422) to commemorate the telescope. Its pattern of stars represents one of the aerial telescopes used at the Paris observatory. These

THE INDIAN

Indus SIZE RANKING

49

BRIGHTEST STAR

Alpha

Indi

ABBREVIATION

Ind

HIGHEST IN SKY AT 10 PM

August–October FULLY VISIBLE

15°N–90°S

This southern constellation was introduced in the late 16th century by Pieter Dirkszoon Keyser and Frederick de Houtman (see panel, right). It represents a human figure

λ

ξ

ARA

INDUS PAVO THE TELESCOPE

19h

20h -60

˚

with a spear and arrows, although it remains unclear whether this is supposed to be a native of the East Indies (as discovered by the Dutch explorers during their expeditions) or a native of the Americas.

(α) 3.1 GENITIVE

ζ

TELESCOPIUM

˚

SCORPIUS

SPECIFIC FEATURES Fifth-magnitude Epsilon (ε) Indi is one of the closest stars to us, being 11.8 light-years away. Somewhat smaller and cooler than the Sun, it appears pale orange in color. Theta (θ) Indi is a 4th-magnitude star with a companion of 7th magnitude that can be identified through a small telescope.

18h

21h

EXPLORING SPACE

DUTCH VOYAGES OF DISCOVERY As well as exploring the southern oceans, Dutch traders and navigators charted the southern sky. On the first Dutch expedition to the East Indies in 1595 were two Dutch navigator–astronomers, Pieter Dirkszoon Keyser (c. 1540–96) and Frederick de Houtman (1571–1627). Keyser died during the voyage, but his celestial observations, along with those of de Houtman, were returned to the Dutch cartographer Petrus Plancius (see p.358 and formed the basis for 12 new constellations, all of which are still recognized.

FAMILY OF EXPLORERS

The first Dutch expedition to the East Indies consisted of four ships and was led by Cornelis de Houtman, the brother of Frederick, who was on the trip as a navigator.

CONCEALED FIGURE 2

Only a vivid imagination could discern the figure of a human in the constellation of Indus, which comprises a few faint stars next to the distinctive figures of Grus and Tucana.

-40

THE INDIAN

˚

MICROSCOPIUM GRUS

T

ζ α

-50

INDUS

˚ δ ε

η

θ β

TH E NI G H T S KY

TUCANA -60

˚

PAVO

-70

˚ OCTANS HYDRUS 0h

23h

21h

THE CONSTELLATIONS

MICROSCOPIUM

417

SCULPTOR

THE CRANE

PISCIS AUSTRINUS

Grus SIZE RANKING

BRIGHTEST STAR

Alnair (α) 1.7 GENITIVE

Gruis

ABBREVIATION

GRUS

45 -40

ρ

˚

PHOENIX

δ1 δ2

θ

Gru

ι

HIGHEST IN SKY AT 10 PM

September–October

γ

λ

β

μ1 μ2 α

FULLY VISIBLE

Alnair

33°N–90°S -50

˚ ζ

Grus represents a long-necked wading bird—a crane—although it has also been depicted as a flamingo. It is a constellation of the southern sky and is situated between Piscis Austrinus and Tucana. Grus was introduced at the end of the 16th century by the Dutch navigator–astronomers Pieter Dirkszoon Keyser and Frederick de Houtman (see panel, opposite). SPECIFIC FEATURES Delta (δ) Gruis is a pair of 4thmagnitude giants, with one yellow component and one red one, while Mu (μ) Gruis is a pair of 5thmagnitude yellow giants. Both pairs are divisible with the naked eye. They appear double due to chance alignments and are not true binaries. Beta (β) Gruis is a red giant whose brightness ranges from magnitude 2.0 to 2.3, with no set period.

ε

INDUS

η

TUCANA 23h

22h

THE CRANE

SHOWING THE WAY 2

Two wide doubles—Delta (δ) and Mu (μ) Gruis—appear along the extended neck of Grus, the Crane, which points to the lower right in this image.

MYTHS AND STORIES

THE PHOENIX

MYTHICAL BIRD

Phoenix SIZE RANKING

37

BRIGHTEST STAR

Ankaa (α) 2.4 GENITIVE

Phoenicis

ABBREVIATION

Phe

HIGHEST IN SKY AT 10 PM

October–November FULLY VISIBLE

32°N–90°S

SPECIFIC FEATURES Zeta (ζ) Phoenicis is a variable double consisting of a 4th-magnitude star with an 8th-magnitude companion. The brighter star is an eclipsing binary and varies between magnitudes 3.9 and 4.4 every 1.7 days.

SCULPTOR

PHOENIX FALLING 2

The stars of Phoenix sink toward the western horizon in the morning sky, with Grus below it. North is to the right in this photograph.

HYDRUS -40

˚

α

PHOENIX

γ

ψ -50

δ

ν

μ

β

Ankaa

ι

κ λ2 λ1

ε

˚ ζ

π η

Achernar -60

THE PHOENIX

˚

TUCANA

1h

0h

T HE N I G H T S K Y

Phoenix lies at the southern end of Eridanus, next to that constellation’s brightest star, Achernar. It is the largest of the 12 southern constellations introduced during the late 16th century by the Dutch navigator–astronomers Pieter Dirkszoon Keyser and Frederick de Houtman (see panel, opposite). It represents the mythical bird that was supposedly born from the ashes of its predecessor (see panel, right).

According to legend, the phoenix was said to live for 500 years. At the end of its life span, it built a nest of cinnamon bark and incense, on which it died, some say in fire. A baby phoenix was born from its ancestor’s remains. The death and rebirth of the FUNERAL PYRE phoenix has been The phoenix is consumed seen as symbolic of by fire in this 18th-century the daily rising and German copper engraving from Bilderbuch für Kinder. setting of the Sun.

418

THE CONSTELLATIONS THE TOUCAN

Tucana 48

SIZE RANKING

BRIGHTEST STAR

Alpha (α) 2.9 Tucanae

GENITIVE

ABBREVIATION

Tuc

HIGHEST IN SKY AT 10 PM

September–November FULLY VISIBLE

14°N–90°S

telescope. In the entire sky, only Omega (ω) Centauri is a more impressive globular cluster than 47 Tucanae. NGC 362, the other globular cluster in Tucana, is smaller and fainter and requires binoculars or a small telescope to be seen. Beta (β) Tucanae is a naked-eye or binocular double with stars of 4th and 5th magnitudes. The brighter component can be further separated through a telescope. Kappa (κ) Tucanae, near NGC 362, is a double star of 5th and 7th magnitudes divisible through a small telescope.

THE SMC 215

This neighboring mini-galaxy, the Small Magellanic Cloud, appears noticeably elongated. To its right in this image lies 47 Tucanae, or NGC 104, a globular cluster in our galaxy.

This far-southern constellation is to be found at the end of the celestial river, Eridanus. It represents the largebeaked tropical bird that is native to South and Central America. Tucana was introduced in the late 16th century by the Dutch navigator–astronomers Pieter Dirkszoon Keyser and Frederick de Houtman (see p.416). SPECIFIC FEATURES Tucana contains the Small Magellanic Cloud (see p.311), the lesser of the two satellite galaxies that accompany our own galaxy. To the naked eye, it appears like a detached patch of the Milky Way and is seven times wider than the apparent diameter of a full moon. Star fields and clusters within the Small Magellanic Cloud can be detected through binoculars or a small telescope. It is about 190,000 lightyears away. Two globular clusters lie near the Small Magellanic Cloud, although both are actually foreground objects in our galaxy and so are not associated with the Cloud. The more prominent of the two is 47 Tucanae (see p.294), which looks like a hazy 4th-magnitude star to the naked eye. It apparently covers the same area of sky as a full moon when viewed through binoculars or a small

47 TUCANAE 215

This bright globular cluster looks like a fuzzy star on wideangle photographs like the one above right, but telescopes reveal it to be an immense swarm of stars. THE TOUCAN

GRUS PHOENIX ERIDANUS Achernar

-60

ν

β ζ

˚ κ

TH E N I G H T S KY

INDUS

γ

HYDRUS -70

η TUCANA ε

δ

α

PAVO

NGC 362 47 NGC 104

SMC

˚ BIRD OF THE SOUTHERN SKIES 2

OCTANS 1h 2h

0h

The Toucan’s huge beak points downward as the constellation sets toward the western horizon. North is to the right in this picture.

THE CONSTELLATIONS THE LITTLE WATER SNAKE

Hydrus SIZE RANKING

61

BRIGHTEST STAR

Beta (β) 2.8 GENITIVE

Hydri

ABBREVIATION

Hyi

HIGHEST IN SKY AT 10 PM

October–December FULLY VISIBLE

8°N–90°S

SPECIFIC FEATURES HYDRUS AND ACHERNAR 2 Pi (π) Hydri is a wide double of 6thThe sinuous little water snake winds its magnitude red giants, although they way across southern skies between the two lie at different distances from us and Magellanic Clouds. The brightest star near it hence are unrelated. It can be split is Achernar in Eridanus (top, right.) readily through binoculars. Pi-1 (π1) is of magnitude 5.6 3h and is to be found about 740 1h light-years away. Pi-2 (π2) lies ERIDANUS much closer to us, being Achernar about 470 light4h years away; HOROLOGIUM it is of PHOENIX α magnitude 5.7. RETICULUM

Hydrus was introduced in the late 16th century by the Dutch navigator–astronomers Pieter Dirkszoon Keyser and Frederick de Houtman (see p.416). It is a constellation of the far-southern sky and is situated between the Large Magellanic Cloud (see p.310) and the Small Magellanic Cloud (see p.311). This constellation represents a small water snake. It should not be confused with the larger constellation Hydra, also identified as a water snake, which has been recognized since the time of the ancient Greeks.

THE PENDULUM CLOCK

Horologium SIZE RANKING

58

BRIGHTEST STAR

Alpha (α) 3.9 GENITIVE

419

-60

˚

ζ

π ε

DORADO

δ

η2 TUCANA

HYDRUS

γ

ν

SMC

LMC -70

˚

MENSA

β

THE LITTLE WATER SNAKE

NGC 1261 is a modest globular cluster dimly detectable through a small telescope. Arp–Madore 1 (AM1) is another globular cluster of note within the constellation Horologium. It is the most distant known globular cluster

from the Sun, being nearly 400,000 light-years away. Because it is of 16th magnitude, a large telescope is needed to detect it.

THE PENDULUM CLOCK

FORNAX

Horologii

ABBREVIATION

Hor

HIGHEST IN SKY AT 10 PM

November–December

CAELUM -40

˚

_

ERIDANUS

b

FULLY VISIBLE

23°N–90°S AM1

-50

Horologium represents a pendulum clock, as used in observatories. Some depictions show its brightest star, Alpha (α) Horologii, marking the clock’s pendulum (as in the illustration here), while others include it as one of the clock weights. This faint and unremarkable constellation of the southern sky lies near the foot of Eridanus and was introduced by the French astronomer Nicolas Louis de Lacaille (see p.422).

NGC 1261 54

The best deep-sky object in Horologium for amateur instruments is NGC 1261, a compact globular cluster of 8th magnitude more than 50,000 light-years from us.

PHOENIX

R

HOROLOGIUM DORADO RETICULUM -60

NGC 1261

TW Achernar

˚ i

h

`

-70

˚

HYDRUS 3h 5h

2h

STELLAR CLOCK 2

The shape of Horologium is reminiscent of a clock with a long pendulum—unlike many of the shapeless constellations invented by de Lacaille.

T HE N I G H T S K Y

SPECIFIC FEATURES R Horologii is a red-giant variable star of the same type as Mira (in Cetus). It ranges between 5th and 14th magnitudes every 13 months or so.

˚

420

THE CONSTELLATIONS 4h

5h

THE NET

3h

Reticulum

ERIDANUS SIZE RANKING

82

HOROLOGIUM

BRIGHTEST STAR

Alpha (α) 3.3 GENITIVE

-50

Reticuli

ABBREVIATION

˚

DORADO

Ret

HIGHEST IN SKY AT 10 PM

December

ε

ι δ α γ

FULLY VISIBLE

23°N–90°S

-60

˚

β

κ

ζ1,2

RETICULUM

Reticulum is a small constellation in the southern sky, near the Large Magellanic Cloud (see p.310). It was introduced by the French astronomer Nicolas Louis de Lacaille (see p.422) and represents the reticule, or grid, in his eyepiece, which he used for measuring star positions.

LMC -70

HYDRUS

˚ THE NET

MENSA

CASTING THE NET 2

SPECIFIC FEATURES Zeta (ζ) Reticuli is a yellow double star. Its 5th-magnitude components can be split through binoculars.

This rhomboidal group of stars lies near the Large Magellanic Cloud, which is too faint to be seen here in the morning sky. The star at upper right is Achernar (in Eridanus).

THE PAINTER’S EASEL

Pictor SIZE RANKING

59

BRIGHTEST STAR

Alpha (α) 3.2 GENITIVE

Pictoris

ABBREVIATION

Pic

HIGHEST IN SKY AT 10 PM

December–February FULLY VISIBLE

26°N–90°S

T HE N I G H T S KY

Pictor was invented by the French astronomer Nicolas Louis de Lacaille (see p.422), who imagined it as an artist’s easel, complete with palette. He originally called it Equuleus Pictoris, although that name has since been shortened. It is a faint constellation of the southern sky, and it is situated beside the constellations Puppis and Columba. SPECIFIC FEATURES Beta (β) Pictoris is 63 light-years away. It is of special interest because, in 1984, astronomers discovered a disk of dust and gas orbiting this blue-white star of magnitude 3.9. The circumstellar disk is thought to be a planetary system in the process of formation. The planets of our solar system are believed to have developed from a similar disk that existed around the Sun shortly after its formation. Iota (ι) Pictoris is a double star with components of 6th-magnitude. These are readily separated through a small telescope.

BETA PICTORIS 43

The bright areas on this professional falsecolor image indicate the circumstellar disk. Distortions in the shape may be due to a planetary system forming around the star.

5h

7h

COLUMBA -40

CAELUM

˚ PUPPIS PICTOR -50

β

Canopus

˚

ι δ

γ DORADO

-60

THE PAINTER’S EASEL

˚

DIVIDING LINE 2

α LMC

RETICULUM

Pictor consists of little more than a crooked line of stars between brilliant Canopus (in Carina), seen here on the left, and the Large Magellanic Cloud.

THE CONSTELLATIONS

421

SUPERNOVA 1987A 3

THE GOLDFISH

Dorado SIZE RANKING

72

BRIGHTEST STAR

This supernova has faded since its dramatic flare-up in 1987. To its upper left in this image is the spiderlike Tarantula Nebula.

Alpha (α) 3.3 GENITIVE

Doradus

ABBREVIATION

Dor

HIGHEST IN SKY AT 10 PM

December–January FULLY VISIBLE

20°N–90°S

Dorado is one of the southern constellations introduced in the late 16th century by the Dutch navigator–astronomers Pieter Dirkszoon Keyser and Frederick de Houtman (p.416). Although known as the goldfish, Dorado in fact represents the dolphinfish found in tropical waters, not common aquarium and pond fish. The constellation has also been depicted as a swordfish. Most of the Large Magellanic Cloud (see p.310) is contained within Dorado, although this mini-galaxy also extends into Mensa. The first recorded mention of the Large Magellanic Cloud is credited to al-Sufi (see panel, below). SPECIFIC FEATURES The Large Magellanic Cloud is a satellite galaxy of the Milky Way. It is situated some 170,000 lightyears away from the Earth and, at first sight, looks like a detached part of the Milky Way. Its numerous star clusters and nebulous patches are brought into

view through binoculars or a small telescope. A remarkable object in the Large Magellanic Cloud is the Tarantula Nebula, or NGC 2070. It is bright enough to be visible with the naked eye and can be seen well through binoculars. A cluster of newborn stars at the heart of the Tarantula Nebula can be detected through binoculars or a small telescope, while photographs show its looping extremities, like a spider’s legs, from which this large nebula of glowing gas gets its popular name. In February 1987 a supernova flared up in the Large Magellanic Cloud. Supernova 1987A, as it was called, reached 3rd magnitude in May of that year, and this made it the brightest supernova visible from Earth since 1604. It remained visible to the naked eye for 10 months. Beta (β) Doradus is one of the brightest Cepheid variables, ranging between magnitudes 3.5 and 4.1 every 9.8 days, while R Doradus is an erratic red giant that varies from 5th to 6th magnitude every 11 months or so.

THE LMC 215

The brighter of the two mini-galaxies that accompany our own, the Large Magellanic Cloud appears elongated in shape. It includes the Tarantula Nebula (here on its upper-left edge). HEADING SOUTH 2

Dorado, the Goldfish, swims through the southern skies, apparently on its way to the south celestial pole.

CAELUM HOROLOGIUM

PUPPIS

γ

Canopus

-50

PICTOR

AL-SUFI Abd al-Rahman al-Sufi (903–86), known also by his Latinized name, Azophi, was an Arabic astronomer. Around AD 964, he produced the Book of the Fixed Stars—an updated version of Ptolemy’s Almagest— which introduced many star names still in use today. Later editions of the book contained Arabic illustrations of the constellations (like the one below).

α

CARINA

˚

ζ β

R

DORADO

δ

LMC

NGC 2070

θ

RETICULUM

VOLANS -70

MENSA

˚

CONSTELLATION PORTRAIT

A version of al-Sufi’s Book of the Fixed Stars was produced in the 16th century by a Persian artist. It included this image of Boötes.

HYDRUS 7h

6h

5h

4h

8h

T HE N I G H T S K Y

THE GOLDFISH

422

THE CONSTELLATIONS magnitude Gamma (γ) Volantis, which is jointly the brightest star in the constellation. This orange star has a yellow companion, of 6th magnitude. They form a beautiful double when viewed through a small telescope. Epsilon (ε) Volantis is another interesting double, although it is not as colorful as Gamma. Its components, which are of 4th and 7th magnitudes, can be detected readily through a small telescope.

THE FLYING FISH

Volans SIZE RANKING

76

Beta (β) 3.8, Gamma (γ) 3.8 BRIGHTEST STARS

GENITIVE

Volantis

ABBREVIATION

Vol

HIGHEST IN SKY AT 10 PM

January–March FULLY VISIBLE

14°N–90°S 9h

8h

This small and faint constellation of the southern sky between Carina and the Large Magellanic Cloud (see p.310) was introduced in the late 16th century by the Dutch navigator–astronomers Pieter Dirkszoon Keyser and Frederick de Houtman (see p.416). It represents the tropical fish that uses its outstretched fins as wings to glide through the air. SPECIFIC FEATURES Although it lies on the edge of the Milky Way, Volans is surprisingly bereft of deep-sky objects. It does, however, contain two good double stars, one of them being 4th-

-60

7h

PICTOR

10h

˚

6h

VOLANS

CARINA

DORADO

-70

˚

MENSA

FISH IN FLIGHT 2

CHAMAELEON

The Flying Fish leaps into the evening sky above the eastern horizon. Beneath it here are the Milky Way and the stars of Carina and Vela, with the False Cross at left. THE FLYING FISH

THE TABLE MOUNTAIN

6h

5h

7h

Mensa

8h SIZE RANKING

75

BRIGHTEST STAR

4h

DORADO

PICTOR

9h

RETICULUM

Alpha (α) 5.1 GENITIVE

LMC

Mensae

ABBREVIATION

Men

HIGHEST IN SKY AT 10 PM

December–February

3h

-70°

VOLANS

FULLY VISIBLE

HYDRUS MENSA

5°N–90°S -80°

TH E N I G H T S KY

TABLE TOP 2

The French astronomer Nicolas Louis de Lacaille (see panel, right) introduced this constellation. It commemorates Table Mountain near the modern Cape Town, South Africa, which is close to where he set up his observatory. When viewing the wispy appearance of the Large Magellanic Cloud (see p.310) in Mensa, de Lacaille may have recalled the clouds sometimes seen over the real Table Mountain. It is the only constellation that de Lacaille did not name after a scientific or artistic tool. Mensa is the faintest of all 88 constellations, and its brightest star, Alpha (α) Mensae, is of only 5th magnitude. Its main point of interest is that part of the Large Magellanic Cloud overlaps into it from neighboring Dorado. Other than this cloud, there is nothing to attract the casual observer to this small constellation of the south polar region of the sky.

The far-southern constellation Mensa appears in this -90° photograph above pinktinged clouds in the dawn sky. THE TABLE MOUNTAIN

NICOLAS LOUIS DE LACAILLE This French astronomer charted the southern skies in 1751–52 from Cape Town, South Africa. Nicolas Louis de Lacaille (1713–62) observed the positions of nearly 10,000 stars, producing a catalog and star chart on which he introduced 14 new constellations. Most of these represented instruments of the arts and sciences. SOUTHERN VIEWPOINT

Lacaille observed the stars from near Table Mountain, which is covered by an attractive “tablecloth” of clouds in this photograph.

423 The constellation was introduced at the end of the 16th century by the Dutch navigator–astronomers Pieter Dirkszoon Keyser and Frederick de Houtman (see p.416).

THE CHAMELEON

Chamaeleon SIZE RANKING

79

Alpha (α) 4.1, Gamma (γ) 4.1 BRIGHTEST STARS

GENITIVE

Chamaeleontis ABBREVIATION

Cha

HIGHEST IN SKY AT 10 PM

February–May FULLY VISIBLE

7°N–90°S

SPECIFIC FEATURES Delta (δ) Chamaeleontis is a wide pair of unrelated stars of 4th and 5th magnitudes. They are easily seen through binoculars. NGC 3195 is a planetary nebula of similar apparent size to Jupiter, but it is relatively faint and so requires a moderate-sized telescope to be seen.

THE CHAMELEON

Chamaeleon was named after the lizard that can change its skin color to match its surroundings. It is a small, faint constellation of the south polar region of the sky.

CARINA

Acrux 14h

9h

CRUX

8h

7h

MUSCA VOLANS

CIRCINUS

γ

ε β

-70°

CHAMAELEON

APUS

α CAMOUFLAGE ARTIST 2

NGC 3195

Chamaeleon lies close to the south celestial pole, which is to the left of it in this picture. To the north of this constellation are found the rich Milky Way star fields of Carina.

-80°

16h

THE BIRD OF PARADISE 18h

Apus

TRIANGULUM AUSTRALE

19h SIZE RANKING

67

BRIGHTEST STAR

Alpha (α) 3.8 GENITIVE

Hadar

CIRCINUS

20h

Apodis

ABBREVIATION

Rigil Kentaurus

ζ

PAVO

Aps

APUS

HIGHEST IN SKY AT 10 PM

May–July -70°

FULLY VISIBLE

β

7°N–90°S

γ -80°

SPECIFIC FEATURES Delta (δ) Apodis is a wide pair of unrelated 5th-magnitude red giants, while Theta (θ) Apodis is a red giant that varies somewhat erratically between 5th and 7th magnitudes every 4 months or so.

THE BIRD OF PARADISE

EXOTIC BIRD 2

Apus, which is south of the distinctive Triangulum Australe, represents a bird of paradise but is a disappointing tribute to such an exotic bird.

θ

η OCTANS

T HE N I G H T S K Y

The constellation Apus is situated in the almost featureless area around the south celestial pole. It was invented in the late 16th century by the Dutch navigator–astronomers Pieter Dirkszoon Keyser and Frederick de Houtman (see p.416).

α

424

THE CONSTELLATIONS THE PEACOCK

Pavo SIZE RANKING

44

BRIGHTEST STAR

Peacock (α) 1.9 GENITIVE

Pavonis

ABBREVIATION

Pav

HIGHEST IN SKY AT 10 PM

July–September FULLY VISIBLE

15°–90°S

Pavo is one of the far-southern constellations that were introduced at the end of the 16th century by the Dutch navigator–astronomers Pieter Dirkszoon Keyser and Frederick de Houtman (see p.416). It represents the

peacock of southeast Asia, which the Dutch explorers encountered on their travels. In more recent times, its brightest star, 2nd-magnitude Alpha (α) Pavonis, was given the name Peacock. In Greek mythology, the peacock was the sacred bird of Hera, wife of Zeus, who traveled through the air in a chariot drawn by these birds. It was Hera who placed the markings on the tail of the peacock after an episode involving Zeus and one of his illicit loves, Io. Although Zeus had disguised Io as a white cow, Hera suspected something was amiss and set the 100-eyed Argus to keep watch on the heifer. Her husband retaliated by sending his son Hermes to release Io. In order to overcome Argus, Hermes told him tales and played music on his reed pipe until the watchman’s eyes closed one by one. When Argus was finally asleep, Hermes chopped off his

head and set Io free. In his memory, Hera then placed the eyes of Argus on the peacock’s tail. The constellation Pavo is to be found on the edge of the Milky Way south of Sagittarius and next to another exotic bird, the toucan (the constellation Tucana). SPECIFIC FEATURES Kappa (κ) Pavonis is one of the brighter Cepheid variables. Its fluctuations, between magnitudes 3.9 and 4.8 every 9.1 days, can be followed with the naked eye. Xi (ξ) Pavonis is a double star with components of unequal brightness— 4th and 8th magnitudes. The fainter star is difficult to identify with the smallest-aperture telescopes because its brighter neighbor overwhelms it. NGC 6752 is one of the largest and brightest globular clusters in the sky. It is just at the limit of naked-eye

visibility but readily located through binoculars. It covers half the apparent width of a full moon. A telescope with an aperture of 3 in (75 mm) or more will resolve its brightest individual stars. The large spiral galaxy NGC 6744 is presented virtually face-on to the Earth. It is visible as an elliptical haze in a telescope of small to moderate aperture. NGC 6744 lies about 30 million light-years away.

NGC 6744 54

This beautiful barred spiral galaxy in Pavo is detectable through a small telescope. The Milky Way might appear like this when viewed from the outside.

NGC 6752 54

The fine globular cluster NGC 6752 remains little-known because of its far-southern declination. The bright star seen above right of it in this image is a foreground object in our galaxy. 20h

21h

19h 18h

SAGITTARIUS

TELESCOPIUM

INDUS

α 1 ϕ2 ϕ ρ –60

˚

γ TUCANA

β

λ

TH E N I G H T S KY

ν

NGC 6744

κ

δ PAVO

SX

ε –70

ARA

NGC 6752

ζ

˚ OCTANS

THE PEACOCK

CELESTIAL DISPLAY 2

The constellation Pavo, the Peacock, is depicted fanning its tail across the southern skies, in imitation of a real-life peacock when attracting a mate.

ξ π

η TRIANGULUM AUSTRALE

THE CONSTELLATIONS THE OCTANT

Octans SIZE RANKING

50

BRIGHTEST STAR

Nu (ν) 3.8 GENITIVE

Octantis

ABBREVIATION

Oct

HIGHEST IN SKY AT 10 PM

October FULLY VISIBLE

0°–90°S

This constellation, which originally was also known as Octans Nautica or Octans Hadleianus, contains the south celestial pole. It was introduced in the 18th century by the French astronomer Nicolas Louis de Lacaille (see p.422). The area of sky in which Octans lies is quite barren. Within naked-eye range, the nearest star to the south celestial pole is Sigma (σ) Octantis. It is of only magnitude 5.4 and thus far from prominent. Because of the effect of precession (see p.64), the positions of the celestial poles are constantly

425

changing. As a result, the south celestial pole is moving farther away from Sigma and toward the constellation of Chamaeleon. There are no bright stars in this area, either, so the region of the south celestial pole will remain blank for another 1,500 years, when the pole will pass just over a degree away from 4thmagnitude Delta (δ) Chamaeleontis. Octans represents an instrument known as an octant, which was used by navigators to help them find their position (see panel, right). It was invented by the English instrument maker John Hadley (1682–1744). SPECIFIC FEATURES Lambda (λ) Octantis is a double star that is divisible with a small telescope. The components are of 5th and 7th magnitudes.

SOUTHERN STAR TRAILS 2

Curving star trails, drawn out by the Earth’s rotation on this long-exposure photograph, emphasize the barren nature of the area around the south celestial pole.

PAVO

23h 0h

–70

1h

ν OCTANS

˚ θ

HYDRUS

β –80

TRIANGULUM AUSTRALE

λ

THE OCTANT

15h

APUS

˚

14h

σ 3h

–90

˚

δ

13h

NAVIGATION 12h

5h

11h

MENSA 6h

10h

7h

CHAMAELEON 8h

EXPLORING SPACE

In 1731, the British mathematician John Hadley built a device called a doubly reflecting octant. The navigator sighted the horizon through a telescope and adjusted a movable arm until the reflected image of the Sun or a star overlay the direct view of the horizon. The altitude of the Sun or star could be read off a scale, from which the navigator could deduce his latitude.

OCTANT

AT THE POLE 2

Octans comprises only a scattering of faint stars. There is no bright star to mark the southern pole, which lies center left in this picture.

T HE N I G H T S K Y

This wood and brass octant is by Browning of Boston. In later designs, the arc was extended from one-eighth of a circle to one-sixth, and the octant became the modern sextant.

MO NT HLY S K Y G U I D E

426

“If the stars should appear one night in a thousand years, how would men believe and adore; and preserve for many generations the remembrance of the city of God which had been shown! But every night come out these envoys of beauty, and light the universe with their admonishing smile.” Ralph Waldo Emerson

AS THE EARTH MAKES its year-long journey around the Sun, the night sky changes its appearance and the stars seem to move from east to west. Depending on the observer’s location, some stars are circumpolar and always visible, but others are seen only at certain times of the year. For example, some stars are seen well in the evening sky in January, but are invisible six months later, when the Earth has moved around its orbit to the opposite side of the Sun. The following section tracks seasonal changes in the night sky for observers in both the Northern and Southern hemispheres. As well as covering the regular annual cycles of the stars and constellations, it charts the positions of the planets and provides an observer’s guide to celestial events, such as meteor showers and eclipses of the Sun and Moon. THE LEONID METEORS

This composite image shows the Leonid meteor shower that occurs in November each year. Also visible are the Sickle, a distinctive group of stars in the constellation Leo (top left), and the planet Jupiter (center).

MONTHLY SKY GUIDE

428

MONTHLY SKY GUIDE

USING THE SKY GUIDES THIS MONTH-BY-MONTH GUIDE

70–73 Star motions and patterns

to the night sky features charts that show the whole sky as it appears from most places on Earth’s surface. It complements the CONSTELLATIONS section, in which detailed maps show smaller areas of sky. For each month, text, tables, and supporting charts identify good objects for observation and show the positions of the planets.

SPECIAL EVENTS

MONTHLY HIGHLIGHTS AND PLANET LOCATORS

62–63 The celestial sphere 64–67 Celestial cycles 68–69 Planetary motion

FULL MOON

NEW MOON

2012 January 9

January 23

2013 January 27

January 11

2014 January 16

January 1, 30

2015 January 5

January 20

2016 January 24

January 10

2017 January 12

January 28

2018 January 2

January 17

2019 January 21

January 6

SPECIAL EVENTS CALENDAR △

introductory pages also feature a planet locator chart. This map shows the band of sky that lies on either side of the ecliptic, the plane close to which the planets always appear. These charts should be used in conjunction with the extra information supplied in the Special Events table, as well as the whole-sky charts and the individual constellation entries (see pp.354–425).

For each month of the year, a double-page introduction highlights different phenomena in the sky. Dates of special events, such as phases of the Moon and eclipses, are listed year-by-year in a table. The main text describes those stars, deep-sky objects, and meteor showers that feature prominently in that particular month—this text complements the whole-sky charts that follow. The

PHASES OF THE MOON

observation from northern and southern latitudes is covered separately in the text

the text highlights the most prominent stars, deep-sky objects, and meteor showers

each month of the year has its own introductory pages

NEPTUNE 430

MONTHLY SKY GUIDE

JANUARY

SPECIAL EVENTS

The introduction to each month contains a Special Events table, which lists the dates of full and new moons, and events such as lunar and solar eclipses, and planetary conjunctions and transits (see p.69). This table also lists the dates when Mercury is at greatest elongation.

PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

January 9 January 27 January 16 January 5 January 24 January 12 January 2 January 21

January 23 January 11 January 1, 30 January 20 January 10 January 28 January 17 January 6

JANUARY

SOUTHERN LATITUDES

In both the Northern and Southern hemispheres, the January evening sky is dominated by the magnificent constellation of Orion, the hunter. He is depicted with raised club and shield, facing Taurus the bull, with his two dogs, Canis Major and Canis Minor, following at his heels. The hazy band of the Milky Way arches from southeast to northwest in northern skies, while in the Southern Hemisphere the Large Magellanic Cloud lies high up in the sky.

The two brightest stars in the entire sky, Sirius in Canis Major and Canopus in Carina, blaze high in the sky for southern observers this month. Orion’s brightest members, Rigel and Betelgeuse, are also high up, and Aldebaran, the brightest star in Taurus, glistens a ruddy color lower in the north. Closer still to the northern horizon, Capella is best placed for observation on January evenings. The rich Milky Way star fields of Carina and Centaurus lie in the southeast. By comparison, the western half of the sky appears almost barren, for it contains only a scattering of stars that are easily visible to the naked eye, the most prominent being 1st-magnitude Achernar, in the southwest at the end of Eridanus.

THE STARS

NORTHERN LATITUDES

THE PLANETS

2014: January 5 Jupiter is at opposition, magnitude -2.7.

THE STARS

2014: January 31 Mercury is at greatest evening elongation, magnitude -0.5.

Sirius, the brightest star in the entire sky, is well displayed on January evenings, twinkling above the southern horizon at midnorthern latitudes. Sirius forms the southern apex of a group of three stars known as the Winter Triangle (see p.436), which is completed by Procyon and Betelgeuse. Directly overhead for midnorthern observers is the yellowish star Capella, which is the most northerly first-magnitude star and the brightest member of Auriga. In the northeast, the Big Dipper stands on its handle, and the Square of Pegasus sinks low in the western sky. In the northwest, the Milky Way passes through Auriga into Perseus and Cassiopeia.

2015: January 14 Mercury is at greatest evening elongation, magnitude -0.6. 2017: January 12 Venus is at greatest evening elongation -4.4. 2017: January 19 Mercury is at greatest morning elongation -0.2. 2018: January 1 Mercury is at greatest morning elongation -0.3. 2019: January 6 Venus is at greatest morning elongation -4.5. ECLIPSES

2018: January 31 A total eclipse of the Moon is visible from Africa, Europe, Asia, and Australia. 2019: January 6 A partial eclipse of the Sun is visible from northeast Asia and north Pacific. 2019: January 21 A total eclipse of the Moon is visible from South America, Africa, Europe, Asia, and Australia.

DEEP-SKY OBJECTS One of the most-photographed sights in the sky, the Orion Nebula (see p.241), lies south of the chain of three stars that makes up Orion’s

belt. The nebula is easily visible through binoculars from most northern latitudes, and even under average skies it can be seen with the naked eye as a hazy patch. Three open star clusters in Auriga—M36, M37, and M38— can be picked out with binoculars.

their peak is short, lasting only a few hours, and their radiant remains low in the northeastern sky until well after midnight.

METEOR SHOWERS

19

ORION NEBULA

DEEP-SKY OBJECTS

Northern observers can observe the Quadrantid meteors around January 3–4 every year. The meteors radiate from a point near the handle of the Big Dipper in Ursa Major, an area which was once occupied by the now-obsolete constellation Quadrans, hence their name. Although numerous—peaking at around 100 an hour—the meteors are faint, so not many can be seen from urban areas. Other drawbacks are that

The Orion Nebula is ideally placed for all southern observers this month, since it is high in the

sky. M41, a large star cluster near Sirius, sits on the zenith for observers around 20°S. Under good conditions, M41 is just visible to the naked eye. The Large Magellanic Cloud (see p.310) in Dorado looks like a detached scrap of the Milky Way lying on the meridian (an imaginary line passing north to south through the zenith) on January evenings. Prominent among its mass of stars is the Tarantula Nebula, which appears to the naked eye as a glowing patch as large as a full moon. The Small Magellanic Cloud (see p.311) in Tucana lies closer to the southwestern horizon.

10°

GEMINI

TAURUS

18

17

TH E N IG H T SK Y

17

16

19

16

18

–30°

SAGITTARIUS

15 19

Antares

18

13

17

16

Procyon

15

14

13

12

11

NOON

Bellatrix

10° 19

14

AQUARIUS 17

Rigel

14

17 14

15

E V E N I N G

0°

11

Spica

18

–10° 13 15

12

S K Y

15 11

–20°

POSITIONS OF THE PLANETS

LIBRA

SCORPIUS Shaula

S

M

O

R

N

I N

K

Y

This chart shows the positions of the planets in January from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on January 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

G

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Fomalhaut

CAPRICORNUS

–30°

–40°

Neptune

–50°

EXAMPLES

16

Jupiter’s position on January 15, 2016

13

Jupiter’s position on January 15, 2013. The arrow indicates that the planet is in retrograde motion (see p.68)

ecliptic celestial sphere celestial equator

key to the colored planet icons position of planet shown by colored dot

time of night (in local time) when this area of sky lies on the meridian (an imaginary line running north–south) arrow indicates that the planet is in retrograde motion (see p.68)

TH E N I G H T S KY

16

PISCES

Mira

–40°

–50°

17

ARIES

12

15

TH E N IG H T SK Y

Earth’s axis of rotation

19

11

18

Betelgeuse

11 12

14

11 13

19

Aldebaran

CANCER

16

14

12

Pleiades

13

16

The two outermost planets, Uranus and Neptune, are shown on magnified insets of the main chart because they move relatively slowly through our sky.

NEPTUNE 13

3PM

15 Regulus

12

18

14

Castor

Hyades

–10°

15

AQUARIUS

14

–20°

16

CETUS

LEO

VIRGO

PISCES 17

6PM

Pollux

OPHIUCHUS

A chain of three stars forms Orion’s belt, south of which can be seen the nebulosity of M42. North is to the top of this picture.

Capella

6AM

0°

18

9PM

3AM

Arcturus

17

△ THE OUTER PLANETS

ORION’S BELT

URANUS 19

MIDNIGHT

18

AQUARIUS

OPEN CLUSTERS

M36 (center), M37 (left), and M38 (right) in Auriga can be picked out from the Milky Way with binoculars. MIDNIGHT

431

M41 is visible to the naked eye as a hazy patch of light, but its full complexity and beauty are brought out only in longexposure photographs and CCD images.

9AM

NOON

ecliptic

photographs illustrate some of the most interesting features to be observed

the planet locator chart shows a portion of the celestial sphere on either side of the ecliptic

GHT

9PM

50º

6PM Capella

40º

30º

or

GEMINI declination coordinates

20º

celestial equator

10º

TAURUS

14

13

Pleiades

ARIES

Aldebaran

PLANET LOCATOR CHARTS △

THE INNER PLANETS ▷

These charts show the positions of the planets at 10:00 pm local standard time on the 15th day of the month. Each planet is represented by a different-colored dot, and the number inside the dot refers to a particular year. Each chart shows the planets’ positions in relation to the 13 constellations along the ecliptic (see p.65), the area in which the planets are always found.

The six planets closest to the Sun are represented on the main body of the chart. Bands along the top and bottom indicate in local time when that area of sky is highest in the sky. However, local sunset and sunrise times will affect the darkness of the sky, and thus the visibility of the planets.

Hyades

12

Betelgeuse

time when an area of sky is visible: evening sky (from sunset to midnight) or morning sky (from midnight to sunrise)

yon

Bellatrix

0º Mira Rigel

-10º

E V E N I N G

S K Y

13

12

USING THE SKY GUIDES

THE WHOLE-SKY CHARTS The introduction to each month is followed by two whole-sky charts. These show the position of the stars at 10:00 pm local time on the 15th day of the month, for both the Northern and Southern hemispheres. They project the half of the celestial sphere (see pp.62–63) that would be visible to a viewer under perfect conditions—that is, without any obstruction to the horizon. Any given star rises four minutes earlier each night compared to the previous night. Thus, the night sky changes subtly from one night to the next and even more dramatically from one month to another. To use the whole-sky charts, determine the color-coded horizon and zenith for your location (below), turn to the appropriate month, and position yourself and the whole-sky chart (right).

429

◁ STAR-MOTION DIAGRAMS

These diagrams show the direction in which the stars appear to move as the night progresses. Stars near the equator appear to move from east to west, while circumpolar stars circle around the celestial poles without setting.

SOUTHERN LATITUDES

433 4 43 33

NORTHERN LATITUDES

T H E N I G H T SKY SK Y

--1 1

0

1

2

3

4

Variable le e star

5

Globular arr cluster

Galaxy axy xy y

STAR MAGNIT UDES S S

Open pen n cluster er

Diffuse use se e nebula ula a

Planetary ta tary ary a y nebula

60°N 6 60 0°N 0 °N N

Horizons zon ons o on n

DEEP-SKY D EEP-SKY SKY Y OB O JECTS S

40 40°N 0°N °N N

20°N

60°N 60 0°N 0°N 0° N

Zeniths Zenit enit iths th hs

40°N 40 0°N °N

POINTS P O INTS O F RE E F ERENC ERENCE RENCE RE NCE CE CE

20°N 0°°N 0°N N

Ecliptic Eclipt Eclipti ticc

South

JANUARY | NORT H ERN L AT I T UD ES LOOKING SOUTH

△ ORIENTATION

SOUTH

zenith

To view the sky to the north, face north and hold the map flat, with the NORTH label closest to your body. One of the color-coded lines around the near edge of the map will relate to the horizon in front of you. To view the south, turn around and reposition the map.

LMC MC MC

CAR

E

T

ULU

North

M

STAR MOTION

Cano Canop C Can anop ano opus u us

VE

HO

LA

CAELU

S

COLUMBA

PPI

G LO

M

O

U

IUM

S

T

H

T

PU

S RO

E

S

O

U

H

RETIC DORADO

PICTOR

W

T

S

A

INA

horizon

PH

O

EN

IX Adh A Ad dha hara ara a ra

LEPUS

XIS

IA

PY TL AN

ERI

N DA

RN

AX

US

Siriu Si S iirius riu iius us

7

gel ige Rig Rige R Ri 2 42 4 M42 M4 M

0

CE

M

I

EAST

HY

RO

S riix ri rix tri atr atrix Bellatr Bell B

tel tel elg llge ge g eu use us se

Be

n an rran ara ara bar ba ES eba deb de lde DE DES Ald A AD A YA HY

RU

S

67 M

star name

PER

38 M38 M3 M M3 M36

orr o to Cassst Ca ux lu olllu Po P

L

EO

M3 M37 M 37 37

GE

4 M44 M4 M44

ES AD EIA PL

AU R I G A

M35 35

M

IN

I

uss lu ullu u gu g Reg Re

CA

1 M1 M

SEU

ARIES

EC E CL LIP LI IPT TIIC TIC T C

ES

E NC

R

SC

N TA SEX

U TA

ORION

Pro

S

CE

on cy

CA

O

PI

WEST

S NI

R

M

N

O

N

R M

A

O

Miir raa

D

TU

S

48

M5

UL

PTO R

SA R U R A JO M

G BI E ER TH IPP D

S

horizon

OM

SS

NG

ED

IO

C 88

A

IA

M8 M 87 87

4

CA

M1 10 03 3

ME

LOPA RDALIS

SA U R A JO M

M81

R

ES N TIC C A NA VE

CE M

G BIG E ER TH IPPP D

riss laris olar Pol Polaris Po

All 88 constellations are featured on the whole-sky charts, as well as any notable deep-sky objects within their boundaries. Well-known and easily recognizable stars, star clusters, and asterism patterns (see p.72) are also labeled.

U R SA MINOR PH

EUS

ar a Miz

39

M

51

01 01 10 1 101 M1 M

De ne b

US

BO

DRACO

E OT

S

T

GN

R

E

O

M29

T

H

S

CY

N

W

E

S

LYR A

M5

NA RO LIS C O REA BO

T 2 92 9 M9 M M92

Veg Ve eg ega ga a

R

T

H

13 13 M1 M

HERCULES

2

O

N

M57 57

OBS OB SER ER V ATION ON N TIMES TI Dat Dat Date Da a ate t

Standard Sta St ta tim time im m

Da Day Daylightay a yl y saving sa savi av av time

December Dec De ec ece 15

Midnight M Mid Mi i

1a 1am am

January Janu an an 1

11 11pm 1p

Mid Mid Midnight dn

January Janu an an 15

10 10pm 0p 0p

11 11pm 1pm

February Febru eb eb 1

9p 9pm pm

10p 10 10pm 0pm

February eb e b 15

8pm 8p pm p m

9p 9pm pm

NORTH

L O O K I N G N O RT H

JANUARY | N ORT H ERN L AT I T UD ES ST ST TA TAR AR A R MAGNIT M MAGNI UDES

PH

-1 -1

0

1

DE D EEP-S E E P-SKY EPEP EP-SKY P -S - SKY S OB JECTS J C 2

3

4

5

Va Var Va Vari ari ar rriable ria ri iab sttar sstar sta ta ta r

Glo G lob lo obular o cllu clus cclu lust lu uster us ust sst

Gal G Ga a alaxy ala al laxy

PO PO OINT OIN INTS IN IN NTS O F REF RE E F ERENCE ER Open Op Ope pe pe cllus cluste cluster cclus clu usste st

Diffu Diffuse Diff Dif D ifff fffu fu fu use nebula nebu n ebu e eb bu bu

Planeta Planetary Pla P Pl lanetary lan la la anetary n nebula neb ne n ebula eb e bula

Ho Ho orizons rizons

60°N °N

EUS 4 32 432 2

CE

OBSERVATION TIMES

40°N 0°°N 0°N 0 °N

20°N 20° 0°N 0° 0 °°N N

Zeniths s

60° 6 60°N 60 0 0°N 0° °°N

40°N 4 40° 40 0°°N 0

20 20° 20 20°N 0°°°N N

Ecliptic Eclipt Eclip clip cl

T H E N IG I G H T SK Y

The stars located near the center of each chart can be seen on the zenith (the point directly overhead), while the stars near the chart’s edge appear close to the horizon. Color-coded lines and crosses are used to identify the horizon and zenith on each of the three latitude projections on each monthly chart.

A

HORIZONS AND ZENITHS ▷

51

△ MAIN FEATURES

M5

M52 52

RT A

3

CE

M

LA

M

1 M10

3

I

PE

C 86 869 9

EAST

31

DR

CA

ar

Miz

BE COM RE A NI CE S 4

M

S

AN

SU

WEST

NG

X

M6

E

GA PE

N LY

S

L M EO IN OR

RS

UM

U

deep-sky object name or number

LEO

AU R I G A

PE

UL

Each whole-sky chart shows an area that equals more than half a celestial sphere because it combines three different projections of the night sky, as seen from three different latitudes on Earth. Each month, the sky charts show the night sky as it appears from 60°–20°N, on the Northern Hemisphere chart, and from 0°–40°S, on the Southern Hemisphere chart.

Ca ap pe pe ellla la a

M34

NG

33 33 M33 M3

TRIA

△ CELESTIAL SPHERE

PIS CES

viewer

constellation name

asterism name

M

M4

SC

46

FO

M41 M 4

CA MA NIS JO R

M993 3

zenith

Standard time

Daylight saving time

December 15

Midnight

1am

January 1

11pm

Midnight

January 15

10pm

11pm

February 1

9pm

10pm

February 15

8pm

9pm

△ OBSERVING TIMES

Each chart shows the sky as it appears at 10:00 pm local standard time, mid-month. However, this view can also be seen at other times of the month, as well as one hour later when local daylight saving time is in use. To view the sky at a time before or after 10:00 pm, you may need to consult a different monthly chart.

▽ DEEP-SKY OBJECTS

Icons are used to represent a selection of deep-sky objects of interest to the amateur astronomer.

▽ STAR MAGNITUDE

60°N

20°N 0° 20°S 40°S

△ LINES OF LATITUDES

DEEP-SKY OBJECTS Galaxy

Globular cluster

STAR MAGNITUDES -1

0

1

2

3

4

5

Variable star

Open cluster

Diffuse nebula

Planetary nebula

T HE N I G H T S K Y

Stars that appear brighter than magnitude 6 are illustrated on the whole-sky charts. This key can be used to gauge their magnitude. About 25 prominent stars are also labeled with their popular names.

40°N

Determine the latitude line that is closest to your geographical location, and use the color-coding on the sky charts to find the view from your location. Note that a 10° difference in latitude has little effect on the stars that can be seen.

Date

430

MONTHLY SKY GUIDE

JANUARY

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

January 9 January 27 January 16 January 5 January 24 January 12 January 2 January 21

January 23 January 11 January 1, 30 January 20 January 10 January 28 January 17 January 6

In both the Northern and Southern hemispheres, the January evening sky is dominated by the magnificent constellation of Orion, the hunter. He is depicted with raised club and shield, facing Taurus the bull, with his two dogs, Canis Major and Canis Minor, following at his heels. The hazy band of the Milky Way arches from southeast to northwest in northern skies, while in the Southern Hemisphere the Large Magellanic Cloud lies high up in the sky.

NORTHERN LATITUDES

THE PLANETS

2014: January 5 Jupiter is at opposition, magnitude -2.7.

THE STARS

2014: January 31 Mercury is at greatest evening elongation, magnitude -0.5.

Sirius, the brightest star in the entire sky, is well displayed on January evenings, twinkling above the southern horizon at midnorthern latitudes. Sirius forms the southern apex of a group of three stars known as the Winter Triangle (see p.436), which is completed by Procyon and Betelgeuse. Directly overhead for midnorthern observers is the yellowish star Capella, which is the most northerly first-magnitude star and the brightest member of Auriga. In the northeast, the Big Dipper stands on its handle, and the Square of Pegasus sinks low in the western sky. In the northwest, the Milky Way passes through Auriga into Perseus and Cassiopeia.

2015: January 14 Mercury is at greatest evening elongation, magnitude -0.6. 2017: January 12 Venus is at greatest evening elongation -4.4. 2017: January 19 Mercury is at greatest morning elongation -0.2. 2018: January 1 Mercury is at greatest morning elongation -0.3. 2019: January 6 Venus is at greatest morning elongation -4.5. ECLIPSES

2018: January 31 A total eclipse of the Moon is visible from Africa, Europe, Asia, and Australia. 2019: January 6 A partial eclipse of the Sun is visible from northeast Asia and north Pacific. 2019: January 21 A total eclipse of the Moon is visible from South America, Africa, Europe, Asia, and Australia.

DEEP-SKY OBJECTS One of the most-photographed sights in the sky, the Orion Nebula (see p.241), lies south of the chain of three stars that makes up Orion’s

belt. The nebula is easily visible through binoculars from most northern latitudes, and even under average skies it can be seen with the naked eye as a hazy patch. Three open star clusters in Auriga—M36, M37, and M38— can be picked out with binoculars.

their peak is short, lasting only a few hours, and their radiant remains low in the northeastern sky until well after midnight.

METEOR SHOWERS Northern observers can observe the Quadrantid meteors around January 3–4 every year. The meteors radiate from a point near the handle of the Big Dipper in Ursa Major, an area which was once occupied by the now-obsolete constellation Quadrans, hence their name. Although numerous—peaking at around 100 an hour—the meteors are faint, so not many can be seen from urban areas. Other drawbacks are that

OPEN CLUSTERS

M36 (center), M37 (left), and M38 (right) in Auriga can be picked out from the Milky Way with binoculars. MIDNIGHT

3AM

6AM

9AM

NOON

LEO

Arcturus 10°

Regulus

12 16 0°

14

TH E N I G H T S KY

17

12

–10°

–20°

11

VIRGO

OPHIUCHUS

18

14

11 19

13

18 17

11

17

16 18

–30°

SAGITTARIUS

19

16

15 19

Antares

18

13

16

14

Spica

18

LIBRA

SCORPIUS Shaula

S

–40°

–50°

M

O

R

N

I N

G

15

K

Y

CANCER

JANUARY

431

SOUTHERN LATITUDES THE STARS

ORION NEBULA

The two brightest stars in the entire sky, Sirius in Canis Major and Canopus in Carina, blaze high in the sky for southern observers this month. Orion’s brightest members, Rigel and Betelgeuse, are also high up, and Aldebaran, the brightest star in Taurus, glistens a ruddy color lower in the north. Closer still to the northern horizon, Capella is best placed for observation on January evenings. The rich Milky Way star fields of Carina and Centaurus lie in the southeast. By comparison, the western half of the sky appears almost barren, for it contains only a scattering of stars that are easily visible to the naked eye, the most prominent being 1st-magnitude Achernar, in the southwest at the end of Eridanus.

DEEP-SKY OBJECTS The Orion Nebula is ideally placed for all southern observers this month, since it is high in the

M41 is visible to the naked eye as a hazy patch of light, but its full complexity and beauty are brought out only in longexposure photographs and CCD images.

sky. M41, a large star cluster near Sirius, sits on the zenith for observers around 20°S. Under good conditions, M41 is just visible to the naked eye. The Large Magellanic Cloud (see p.310) in Dorado looks like a detached scrap of the Milky Way lying on the meridian (an imaginary line passing north to south through the zenith) on January evenings. Prominent among its mass of stars is the Tarantula Nebula, which appears to the naked eye as a glowing patch as large as a full moon. The Small Magellanic Cloud (see p.311) in Tucana lies closer to the southwestern horizon.

19

MIDNIGHT

ORION’S BELT

URANUS

18

A chain of three stars forms Orion’s belt, south of which can be seen the nebulosity of M42. North is to the top of this picture.

PISCES 17

16

9PM

15

14

NEPTUNE 13

12

19

18

6PM

17

16

15

14

CETUS

13

Capella

12

11

AQUARIUS

3PM

Castor

GEMINI

Pollux

TAURUS

14

Pleiades

ARIES

13

NOON

Aldebaran Hyades

12

PISCES

10°

Betelgeuse Procyon

Bellatrix

19

AQUARIUS

Mira

17

Rigel

17 14

15

E V E N I N G

0°

11

12

S K Y

–10° 13 15

15 11

–20°

POSITIONS OF THE PLANETS

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Neptune

Jupiter’s position on January 15, 2016

CAPRICORNUS

–30°

–40°

–50°

EXAMPLES

16

Fomalhaut

13

Jupiter’s position on January 15, 2013. The arrow indicates that the planet is in retrograde motion (see p.68).

T HE N I G H T S K Y

This chart shows the positions of the planets in January from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on January 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

W

E

M33 M

NG SI

PE

O

RS

ED

C

U S

NG 84

C

M1 03

C8

2

869

S

S

N

31

A

UM

O R M5

7

LYR A

EPH EU

M5

PE IA

NG

E US

CA S

4

OM 39

en eb

D

C

YG N

M3

UL

DR L

M

RT A

9

AC E

M2

T Variable star

C

AM

Vega

Globular cluster

DEEP-SKY OBJECTS Galaxy

ella

Cap

AU R I G A

ELO PARDALIS

Polaris

U R SA MINOR

DRACO

M92

HERCULES

NORTH

L O O K I N G N O RT H

Open cluster

Diffuse nebula

X

M 13

N LY

M81

Planetary nebula

G BI E ER TH IPP D

ar Miz 1 M10

SA R U R A JO M

NA RO LIS C O REA BO

60°N

40°N

M

O

ES N TIC CA NA VE

Date

December 15 January 1 January 15 February 1

T

60°N

February 15

Zeniths

E OT

N

R

I

H

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES

S

L M EO IN OR 51

BO

20°N

POINTS OF REFERENCE Horizons

Daylightsaving time

1am

Ecliptic

Midnight

11pm

10pm

9pm

20°N

EAST

TRIA

AN

T

5

M87

PIS CES

S

4

LEO

TH E N I G H T S KY

H

3

3

BE COM RE A NI CE M6 S 4

M5

SU 1

3

M

T

S

A

E

GA PE

0

STAR MAGNITUDES -1

2

JANUARY | NOR THE R N L AT I T UD E S

WEST

432

AN XT

u Reg lus

O

S

T

48

LA

M

TL AN IA

S

VE

ER

A

D M9 3

PU

7

R

M5

N

0

S

S

CAR

PPI

O

INA

RO

S

M41

Sirius

CE

Adhara

CA MA NIS JO R

M4

I

R

O

U

5

se

LEPUS

Rigel

M42

Bellatrix

RET

LOOKING SOUTH

SOUTH

LMC

DORADO

M

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

S

ARIES

IUM

Horizons

60°N

40°N

20°N

Zeniths

O

TU

S

PH

AX

CE

N OR

ra

F

Mi

POINTS OF REFERENCE

G LO RO

US

HO

N DA ERI

RU

ES

AD

U TA

P

S

I LE

SEU

UM ICUL

CAELU

DES

HYA

aran

Aldeb

ORION

M1

AU R I G A

COLUMBA

PICTOR

Canopus

lgeu

Bete

M3

PER

JANUARY | NOR TH E R N L AT I T UD E S

EAST M

E

HY 46

S NI

H

XIS

67

PY

CA

O

on

N

cy

M

o Pr

T

A

TIC M37

M38 M36

ES SC

SE

PI

M

S

M44

C CAN

T

60°N

O

U

IX

ECLIP

x

EN

llu Po

O

H

W

M

T

R 40°N

20°N

South

North

Ecliptic

STAR MOTION

S

tor

E

Cas

S

I

PTO

LE

IN

CU L

G

EM

WEST

433

M 33

M

PE

TA

S

D

A

N

US

ES

Rig el M42

M36

M35

N

O

31

R T

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

us

Siri

Planetary nebula

M5

0

M

47

OS c Pro

M46

INI

O

yon

x

X

lu Pol

tor Cas

1

LYN

M8

Horizons

0°

CER 4

CAN M4

20°S

M

40°S

67

UR

SA

R

T

s lu gu Re

O

M

N

H

Midnight

Standard time

11 pm

Midnight

1 am

Daylightsaving time

9 pm

40°S

Ecliptic

10 pm

11 pm

20°S

8 pm

9 pm

10 pm

OBSERVATION TIMES Date

December 15 January 1 January 15 February 1

0°

February 15

Zeniths

RA HYD

POINTS OF REFERENCE

D R AC

GEM

R INO CANIS M

MONOC ER

IS MAJOR

Betelgeuse

CAN

M37

ORION

M1

Bellatrix

Aldebaran

M38

AURIGA Capella

NORTH

L O O K I N G N O RT H

MELO PARDALIS

HYAD

CA

US

S Variable star

8 M4

LEP

UR U

DES

PLEIA

R

84

SE US

C8

I

NG

ER

S 69

M1 03

C8

M3 4

NG

UM

US

P EIA

UL

IE S

IO

AN G

AR

CET

I

TIC

ra

M

C AS S

ED A

TR

EC LIP

Mi

CE N DR O

T

5

S

TH E N I G H T S KY

A

E

S

4

EAST

PIS

H

W

3

SE

XT AN

O

OR

AS U 1

R

LE

IN

M

T

O

LE

S

A

E

JO

A

PEG 0

STAR MAGNITUDES -1

2

JANUARY | S OUTHE R N L AT I T UD E S

WEST

434

H

S

U RV CO

EAST

S

O

U T

A S T

39

RU

51

N TA U

C

S

A

LU

ux

Ga cr

PU S

x

CIRC

aur us

ar

Had

il K ent

Rig

Acru rux

Bec

UX

LA

CR

VE

INUS

MUS

Canopus

MAJO

O

M E N SA

SOUTH

ARA

OCTANS

PAVO

LOOKING SOUTH

TRIANG UL AUSTRA UM LE

APUS

BA

UM

DORAD

CAEL

COL UM

ER

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

A ID

SMC

Diffuse nebula

Planetary nebula

e

S

OE

U IND

PH

NI

X

GR

Horizons

0°

20°S

40°S

POINTS OF REFERENCE

A

r rna

N TUCA

04 C1

US

NG

HYDR

M

Ach

IU

U

S

N

G LUM HOROLO LMC RETICU

R

LEPUS

CHAMAELEON

NS

PICTOR

A

VOL A

RIN

IS

CA

PP

CA

PU

a

har

Ad

NIS AX

RN FO

S TU

CE RO

Zeniths

M

US

IC

L P TO R

CA

JANUARY | SO UT HE R N L AT I T UD E S

E

CE

NG

A S

R

CU

TE RA

I

S

S

O

0°

T

IU

U

P CO

H

M

A P U ST ISC R IS I N US

W

TL AN

T

C

S

t

S 20°S

40°S

South

North

Ecliptic

STAR MOTION

S

3

E

DR

RIU

HY

XI

AQ UA

PY

au

M9

alh

41

Fo m

M

WEST

435

436

MONTHLY SKY GUIDE

FEBRUARY

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

February 7 February 25 February 14 February 3 February 22 February 11 None February 19

February 21 February 10 None February 18 February 8 February 26 February 15 February 4

Castor and Pollux, the brightest stars in the northern zodiacal constellation of Gemini, lie close to the celestial meridian (the imaginary north–south line in the sky) on February evenings, as does Procyon in Canis Minor, which adjoins Gemini to the south. In the Southern Hemisphere, Carina, Puppis, and Vela—the three constellations that once formed the large ancient Greek constellation Argo Navis, ship of the Argonauts—are high in the sky.

PLANETS

NORTHERN LATITUDES

2013: February 8 Mercury and Mars are 0.5° apart in the western evening sky.

THE STARS

2013: February 16 Mercury is at greatest evening elongation, magnitude -0.5.

stars three times wider than a full moon; under ideal conditions, it can be glimpsed by the naked eye as a hazy patch—it was known to the ancient Greeks. The Milky Way runs through Monoceros, an often-overlooked constellation framed by the Winter Triangle, which contains several open star clusters. One of the most notable of these clusters, NGC 2244, is visible through binoculars. It is located at the heart of the elusive Rosette Nebula, which is seen well only in photographs.

Gemini is almost overhead as seen from mid-northern latitudes in February, with the faintest of the zodiacal constellations, Cancer, close by but slightly lower in the sky. South of Gemini, the sparkling Winter Triangle formed by Sirius (in Canis Major), Betelgeuse (in Orion), and Procyon (in Canis Minor) remains prominent. Taurus, the Bull, backs away from Orion toward the western horizon, with Auriga and Perseus higher above it. Close to the northwest horizon is the W-shaped Cassiopeia. Leo, the Lion, is moving into the eastern sky, with the familiar figure of the Plough above it in the northeast.

2015: February 6 Jupiter is at opposition, magnitude -2.6. 2015: February 21 Venus and Mars are 0.4° apart in the western evening sky. 2015: February 24 Mercury is at greatest morning elongation, magnitude 0.1. 2016: February 7 Mercury is at greatest morning elongation, magnitude 0.0. 2019: February 27 Mercury is at greatest evening elongation, magnitude -0.4. ECLIPSES

2017: February 26 An annular eclipse of the Sun is visible from Pacific Ocean, Chile, Argentina, Atlantic Ocean, and Africa. A partial solar eclipse is visible from southern South America, Atlantic Ocean, and Antarctica. 2018: February 15 A partial eclipse of the Sun is visible from southern South America and Antarctica.

THE WINTER TRIANGLE

Brilliant Sirius (bottom) forms a prominent triangle in the northern winter sky with Procyon (top, left) and Betelgeuse (top, right).

NEPTUNE 19

DEEP-SKY OBJECTS

18

M35, a large open star cluster at the feet of Gemini, is easily seen through binoculars. The Beehive Cluster (see p.290)—also known as M44 or Praesepe—lies nearby in Cancer. Through binoculars, the Beehive is visible as a scattering of

17

16

15

14

13

MIDNIGHT 12

AQUARIUS 3AM

NOON 6AM

20°

9AM 10°

LEO

Arcturus

Regulus 12

Altair

16 0°

OPHIUCHUS –10°

TH E N I G H T S KY

16

14

15 16

16

14 12

CAPRICORNUS 13

–20°

VIRGO

19

16 19

18

17 19

15 18

13

Spica

14 18

Antares

LIBRA

–30°

SAGITTARIUS

Shaula

–40°

SCORPIUS

N G N I R M O

S K

17

Y

FEBRUARY

437

SOUTHERN LATITUDES THE STARS

DEEP-SKY OBJECTS

Sirius (see p.268) and Canopus, the two brightest stars in the entire sky, remain high for southern observers throughout February, while Achernar, the 1st-magnitude star at the end of the celestial river Eridanus, sinks toward the southwestern horizon. In the southeast, Crux, the Southern Cross, enters the scene, followed by the bright stars of Centaurus. Higher up is the False Cross, which is formed by four stars in Vela and Carina and is sometimes mistaken for the true Southern Cross. Due north lie Castor (see p.276) and Pollux in Gemini. Orion is also high in the sky, with Taurus lower in the northwest. As seen from the most southerly latitudes, Perseus has already set and Auriga is following. Meanwhile, looking northeast, the distinctive shape of Leo, the Lion, has come into view.

The Milky Way, which meanders from southeast to northwest this month, contains numerous star clusters, of which M46 and M47, adjacent in Puppis, are prominent. Both clusters are at the edge of naked-eye visibility and look superb through binoculars. Two other open clusters that can be seen excellently through binoculars are NGC 2451 and NGC 2477, also in Puppis; farther south, in Vela, IC 2391 and IC 2395 are also good examples. Outside the boundaries of the Milky Way, the open cluster M41 is found south of Sirius, while in the north, the Beehive Cluster (see p.290), or M44, is well positioned for observation in both February and March. In Carina, another open cluster, NGC 2516, is prominent. The Large Magellanic Cloud and the Tarantula Nebula are on view, south of Canopus, in the constellation Dorado.

FINDING THE SOUTH CELESTIAL POLE

The south celestial pole (left) is not marked by a bright star, but it can be located by intersecting two imaginary lines. One is the extension of the long axis of Crux. The other is at right angles to the line joining Alpha (α) and Beta (β) Centauri.

URANUS 19

18

9PM

PISCES 17

16

6PM

15

14

13

MIDNIGHT

12

Capella

CETUS

3PM

Castor

NOON

Pollux

Pleiades

GEMINI 14

ARIES

13 Aldebaran

15

TAURUS

Hyades

CANCER

20°

12

19

PISCES

Betelgeuse Procyon

17

Bellatrix

10° 17 12

15 Mira

AQUARIUS

19 15

13 13

Rigel

E V E N I N G

18

S K Y

Saturn

Venus

Jupiter

Uranus

February 15, 2013

–30°

–40°

Neptune

EXAMPLES

13 Jupiter’s position on

Fomalhaut

14 Jupiter’s position on February 15, 2014. The arrow indicates that the planet is in retrograde motion (see p.68).

–50°

T HE N I G H T S K Y

This chart shows the positions of the planets in February from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on February 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

Mars

–10°

–20°

POSITIONS OF THE PLANETS

Mercury

0°

IA

G

W

LU

M

AN

DES 31

US

I

SE

SS

R

CA

CA

RT A

M1 03

884

69

NG C

C8

IA

NG

OP E

DR L

AC E

Ca A U pe RI lla G

M52

O M39

A

ALIS

EUS

LYN

X

Polaris

NORTH

U R SA

M

R

N

O

R T

M

34

3

4

5

Variable star

Globular cluster

DEEP- SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

Planetary nebula

RS U JO A M IG EB R TH IPPE D

CO

a Veg

DRA

LYRA

NO

81

MI

L O O K I N G N O RT H

M29

CYGNUS

Deneb

CEPH

M E LOP ARD

M38

ED A

M

PLEIA

T

PE

33

S

M

E

M

N S

H

U

A RIES

SU 2

2

RC

r

UL

iza 1 10

HE

M9

M

M 60°N

ES

40°N

20°N

POINTS OF REFERENCE Horizons

M

13

S

O

R

COOR B

N

T

H

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES Date January 15 February 1

60°N

February 15 March 1 March 15

Zeniths

Daylightsaving time

1am

Ecliptic

Midnight

11pm

10pm

9pm

20°N

EAST

TR GA PE 1

us

3

TH E NI G H T S KY

PISCES 0

STAR MAGNITUDES -1

tur

Arc

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4

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A

R

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M3

OT E BO

C BE OMA RE NIC E

R EAON LI A S

C VE ANES NA TIC I 51 M

L M EO IN OR

FEBRUARY | NO R THE R N L AT I T UD ES

WEST

438

H

S

S

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S

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IA

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7

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44

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CARINA

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Procyon

LOOKING SOUTH

NC

GEM

I NI

37 M

C

us anop

Adha

ra

MAJ CANIS

M41

us Siri

36

0

1

2

THE NIGHT SKY

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

2

ORI

UM

S

ES AD Y H

Horizons

60°N

40°N

20°N

POINTS OF REFERENCE

O

EL

PU

AD

CA

LE

l ge Ri

R DO

BA

ON

ran eba

ix latr Bel

Ald

M4

R TO

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M1

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OR

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e

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Bet

IGA

M35

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S

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TA

U

M

FEBRUARY | NO R TH E R N L AT I T UD ES

A

A

E

R

S

TE

SE

s

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M

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Castor

S

T

I

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60°N

O

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ER

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D A

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S

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S

VIR

4 10

FO

M

Mira

40°N

20°N

South

North

Ecliptic

STAR MOTION

S

C

VU OR

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CR

W

7

NA X

M8

O

T

LE

WEST

439

D

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AN US

H Y AD ES

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42

ON

38

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LU

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M3

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Be ll

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AM

M

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l

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Variable star

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M47

M46

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48

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L O O K I N G N O RT H

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M37

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

7

HY

M81

M6

Planetary nebula

ulu g Re

s

URS

0°

LE

O

NO

OR

MI

AJ

LEO

AM

IG EB TH PER DIP

20°S

R

40°S

POINTS OF REFERENCE Horizons

r iza M

N

C VE

O

R

H

IC

B

PT LI EC

T

20°S

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES Date

January 15 February 1

0°

February 15 March 1 March 15

Zeniths

Daylightsaving time

1am

Ecliptic

Midnight

11pm

10pm

9pm

40°S

TH E N I G H T S KY

S

S

EI A

SE U

PL

RU

R

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IES

S

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AR

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87

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STAR MAGNITUDES -1

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FEBRUARY | S OUTHE R N L AT I T UD ES

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CARINA

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104

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

BA

T UC

A

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Horizons

0°

20°S

40°S

O

EN

IX Zeniths

PH

A ID

GR

r rna he Ac

M

ER

POINTS OF REFERENCE

AN

H

M

G LO ORO

U EL

DO

CA

SMC

US

S INDU

NGC

HYDR

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LUM

DORA

C

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PICTO

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CHA MAELEON TRI ANG AU S U L U M TRA LE

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x

CR

x

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Be cru

rus

tau

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51

NT AU R

NG

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41

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N

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FEBRUARY | S OUTH E R N L AT I T UD ES

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H

M

IS

A

ra

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M

S

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R

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N

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E

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R

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IA

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40°S

South

North

Ecliptic

STAR MOTION

T

X

S

TE C RA TU

D HY TO R

TL AN

CE

PY

LP

M93

441

WEST

442

MONTHLY SKY GUIDE

SPECIAL EVENTS PHASES OF THE MOON FULL MOON

NEW MOON

2012 March 8

March 22

2013 March 27

March 11

2014 March 16

March 1, 30

2015 March 5

March 20

2016 March 23

March 9

2017 March 12

March 28

2018 March 2, 31

March 17

2019 March 21

March 6

PLANETS

2012: March 3 Mars is at opposition, magnitude -1.2. 2012: March 5 Mercury is at greatest evening elongation, magnitude -0.3. 2012: March 27 Venus is at greatest evening elongation, magnitude -4.3. 2013: March 31 Mercury is at greatest morning elongation, magnitude 0.3. 2014: March 14 Mercury is at greatest morning elongation, magnitude 0.2. 2014: March 22 Venus is at greatest morning elongation, magnitude -4.3. 2016: March 8 Jupiter is at opposition, magnitude -2.5. 2018: March 15 Mercury is at greatest evening elongation, magnitude -0.3. ECLIPSES

2015: March 20 A total eclipse of the Sun is visible from the Faroes (between Scotland and Iceland), the Norwegian Sea, and Svalbard. A partial solar eclipse is visible from Europe, North Africa, and northwestern Asia.

MARCH Nights grow shorter in the Northern Hemisphere, but longer in the Southern Hemisphere, as the Sun moves toward the equinox on March 20. On that date, the Sun lies exactly on the celestial equator, and all over the world day and night are of equal length. For northern observers, Orion and the other brilliant constellations of winter are departing toward the western horizon, while for southern observers the rich star fields of Carina and Centaurus are moving to center stage.

NORTHERN LATITUDES THE STARS The distinctive sickle-shaped group of stars that makes up the head of Leo, the Lion, takes pride of place in the northern evening sky this month, with the fainter stars of Cancer to its right. Below it, in the south, lies a blanklooking area of sky occupied by the faint constellations Sextans, Crater, and Hydra. The only notable star in this area is 2nd-magnitude Alphard (in Hydra)—which, appropriately, means “the solitary one”—lying on the north–south meridian. The saucepan shape of the Big Dipper rides high in the northeast, its handle pointing down toward

the bright star Arcturus, in Boötes, which is the harbinger of northern spring. Closer again to the horizon is Spica in Virgo. In the west, the stars of Gemini and Auriga remain high, with Taurus and Orion lower down. Sirius twinkles near the southwest horizon.

DEEP-SKY OBJECTS The beautiful spiral galaxy M81 (see p.314) in northern Ursa Major, lies near the north–south meridian on March evenings and is detectable through binoculars in clear skies. Farther south, the Beehive cluster (see p.290), or M44, in Cancer remains well positioned for observation.

THE SICKLE OF LEO

The stars that represent the head and neck of Leo, the Lion, form a distinctive shape like a sickle or a reversed question mark.

NEPTUNE

2016: March 9 A total eclipse of the Sun is visible from Indonesia and the North Pacific. A partial solar eclipse is visible from east Asia, Australia, and Pacific Ocean.

19

18

17

16

15

14

13

MIDNIGHT 12

11

AQUARIUS 3AM 20°

6AM

10°

Altair

AQUARIUS

0°

13

TH E N I G H T S KY

17

12 16

14

19

–20°

14

SAGITTARIUS 19

Fomalhaut –30°

VIRGO

OPHIUCHUS

13 –10°

Arcturus

CAPRICORNUS

15

17 19

18 18

16

16

13

14

14 Spica

18

Antares

LIBRA

SCORPIUS Shaula

S R N O M

I N

G

K

Y

MARCH

443

SOUTHERN LATITUDES THE STARS

DEEP-SKY OBJECTS

Leo, the Lion, and its brightest star Regulus (see p.253) are high in the northern half of the sky for all southern observers, with Castor (see p.276) and Pollux in Gemini lower in the northwest. Sirius (see p.268) still sparkles high in the western sky, but Orion sinks on its side toward the western horizon. Almost overhead for observers in mid-latitudes is Alphard, the brightest star in the constellation Hydra, which sprawls across an otherwise barren region of sky toward the southeast horizon. Spica, the brightest star in Virgo, is well-placed in the east, and Canopus, in Carina, is prominent in the southwest sky. However, the main focus of attention is in the southeast, where the Southern Cross, Crux, now rides high along with brilliant Alpha (α) and Beta (β) Centauri— Rigil Kentaurus (see p.252) and Hadar—which point toward it.

An open star cluster popularly known as the Southern Pleiades, IC 2602 lies close to the meridian on March evenings. Its brightest member, 3rd-magnitude Theta (θ) Carinae, is easily visible to the naked eye, and binoculars reveal at least two dozen more members. Four degrees to the north of the Southern Pleiades lies a large glowing region visible to the naked eye, NGC 3372, also known as the Carina Nebula (see p.247), which contains the erratic variable star Eta (η) Carinae (see p.262). Farther north, between Antlia and Vela, telescopes will pick up the planetary nebula NGC 3132, also known as the Eight-Burst Nebula. On view in the southwest sky are the Large Magellanic Cloud and the Tarantula Nebula (in Dorado). URANUS 19

18

THE FALSE CROSS

Two stars in Vela (top left and center right) and two in Carina (center left and bottom right) form the False Cross in the southern sky.

17

PISCES 16

15

14

13

12

6PM 9PM 3PM

CETUS

Capella

MIDNIGHT

NOON

Castor

GEMINI 30°

Pollux Pleiades 14

LEO

15

12

ARIES

13

TAURUS

Aldebaran Hyades

CANCER

19

20° 12 12

PISCES 17

Regulus

15

Betelgeuse

16

17

15

Bellatrix

Procyon

10°

18 18

12 13

0°

Mira Rigel –10°

V

N

G

–20°

POSITIONS OF THE PLANETS

This chart shows the positions of the planets in March from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on March 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Neptune

EXAMPLES

13

Jupiter’s position on March 15, 2013

14 Jupiter’s position on March 15, 2014. The arrow indicates that the planet is in retrograde motion (see p.68).

–30°

T HE N I G H T S K Y

E

E

I N

Y S K

AD HY

Ald

ES

eb M

G

n

ara

U LU

M

M

IG A

US

1

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PL ES

TR

38

ED A

C ap ell a

M

DA LIS

M

PEIA

3

SIO

M10

EL OP AR

4

9

CA S

86

88

C

GC

NG

N

CA

7

IA

CE

S OM

M3

36

E RS E

M 34

A

ND R

M

AD

N

S

R AU

45

PIS 33

H W

E

T

M3

US

IES

N

O

R T

P

2

3

4

5

Variable star

LY N X

M81

Open cluster

Diffuse nebula

Planetary nebula

b Dene

THE BIG DIPPER

R INO U R SA M Polaris

CEPHEUS

M39

NORTH

L O O K I N G N O RT H

LACERTA

M52

Globular cluster

DEEP-SKY OBJECTS Galaxy

NU

O AC

CYG

DR

9

CA

M2

M

1 10

S

60°N

LYR

40°N

A

ga Ve

20°N

POINTS OF REFERENCE Horizons

M3 M

92

M

57

M

N

13

O

R

T

H

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES Date

60°N

February 15 March 1 March 15 April 1 April 15

Zeniths

Daylightsaving time

1am

Ecliptic

Midnight

11pm

10pm

9pm

20°N

EAST

TH E NI G H T S KY

AR 1

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UT

AP

SC

EN

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STAR MAGNITUDES -1

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MARCH | NO R THE R N L AT I T UD E S

WEST

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SOUTH

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0

1

2

THE NIGHT SKY

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

M48

ER

x

Ad

h

s riu Si

50

B

M

s

M

41

pu no Ca

Horizons

60°N

40°N

OR

M1

20°N

OR

IO

N

Zeniths

AJ

se eu elg t e

S NI CA ara

M

5 M3

POINTS OF REFERENCE

INA

P

IS

S

47

3

M

RO

M9

P UP

M46

MON

IS

NI

OR

MI

N MI

GE

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CAR

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MARCH | NOR TH E R N L AT I T UD E S

H

M

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Sp

ECLIPTIC

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South

North

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STAR MOTION

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M5

NU

M

M

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S U R JO A M

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M4 8

M67

H YDR A

NORTH

Open cluster

Diffuse nebula

SE

AN XT

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LEO

R

Planetary nebula

DRA

Horizons

CA

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SV

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20°S

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3

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11pm

Midnight

Standard time

10pm

11pm

Midnight

1am

Daylightsaving time

Ecliptic

10pm

40°S

9pm

20°S

9pm

M5

8pm

OBSERVATION TIMES Date

0°

February 15 March 1 March 15 April 1 April 15

Zeniths

1 10

51

I

64

M

M

IC AT

40°S

POINTS OF REFERENCE

BIG THE ER P DIP

JO R U R SA M A

LEO MINO

M81

L O O K I N G N O RT H

CAN CER M44

LYNX

Globular cluster

DEEP-SKY OBJECTS Galaxy

us

TH E NI G H T S KY

IDA

E

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4

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Spica

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STAR MAGNITUDES -1

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MARCH | S OUTHE R N L AT I T UD E S

WEST

446

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T HE N I G H T S K Y

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STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

A

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SMC

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H YD

MEN

R

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40°S

M

Zeniths

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0°

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M41

M

AJ OR BA

POINTS OF REFERENCE

RUS

ha

s pu no Ca

Ad

PIC

PI S

M93

PUP

LMC

RINA

VOLANS

CA

LOOKING SOUTH

SOUTH

INDUS

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x

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tau

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MARCH | SO UT HE R N L AT I T UD E S

es

6

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S

NG

N TA U

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0

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la

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83

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40°S

South

North

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STAR MOTION

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S

W

PYXIS

ER

M

NA X

VIR

ID AN

U RV CO

T

CE

S

H

WEST

447

448

MONTHLY SKY GUIDE

APRIL

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

April 6 April 25 April 15 April 4 April 22 April 11 April 30 April 19

April 21 April 10 April 29 April 18 April 7 April 26 April 16 April 5

One of the most familiar patterns in the sky, the seven stars that make up the Big Dipper lie overhead from mid-northern latitudes, with the crouching figure of Leo, the Lion, reigning farther south. In the eastern sky, the daffodil-colored Arcturus, in Boötes, announces the arrival of spring in the north. In southern latitudes, the Southern Cross lies close to the north–south meridian, and Alpha (α) and Beta (β) Centauri—Rigil Kentaurus and Hadar—are high in the southeast.

PLANETS

2012: April 15 Saturn is at opposition, magnitude 0.2.

NORTHERN LATITUDES

2012: April 18 Mercury is at greatest morning elongation, magnitude 0.5.

THE STARS

2013: April 28 Saturn is at opposition, magnitude 0.1. 2014: April 8 Mars is at opposition, magnitude -1.5. 2016: April 18 Mercury is at evening elongation, magnitude 0.2. 2017: April 1 Mercury is at evening elongation, magnitude -0.1. 2017: April 7 Jupiter is at opposition, magnitude -2.5. 2018: April 29 Mercury is at morning elongation, magnitude 0.5. 2019: April 11 Mercury is at morning elongation, magnitude 0.4. ECLIPSES

2014: April 15 A total eclipse of the Moon is visible from North America, South America, and New Zealand. 2014: April 29 A partial solar eclipse is visible from west Australia. 2015: April 4 A total eclipse of the Moon is visible from western North America, east Asia, and Australia.

On April evenings, the Big Dipper is high in the sky. The stars in the bowl point north to Polaris (see pp.278–79), the north Pole Star, while following the curve of its handle leads to Arcturus, in Boötes, which is the brightest star north of the celestial equator. Continuing this curve leads to Spica, the brightest star in Virgo, close to the southeastern horizon. South of Leo and Virgo, the sprawling figure of Hydra occupies a large but mostly blank area of sky. By April, most of the stars of winter have disappeared in the west, although Gemini remains on view and Capella, in Auriga, twinkles in the northwest.

DEEP-SKY OBJECTS

large open star cluster worthy of attention can be found in Coma Berenices and consists of a scattering of stars of 5th magnitude and fainter fanned out over an area of sky several times wider than a full moon. Known as the Coma Star Cluster, this is best viewed through wide-angle binoculars. To its south is the Virgo Cluster (see p.329); a telescope is needed to see its numerous but faint member galaxies.

THE BIG DIPPER

The familiar shape of the Big Dipper can be seen high in the sky on northern spring evenings.

METEOR SHOWER One of the weaker annual meteor showers, the Lyrids reaches its peak around April 21–22, when a dozen or so meteors per hour can be seen radiating from a point near Vega (see p.253) in Lyra. Although not numerous, Lyrids are bright and fast. Rates are highest toward dawn, when Vega is highest in the sky, and they are much lower for a day or so on either side of the peak.

NEPTUNE 19

18

17

M81 (see p.314), the beautiful spiral galaxy in northern Ursa Major, is well placed for observation this month. A

16

15

14

13

12

11

AQUARIUS

9AM

30°

MIDNIGHT

20°

3AM

6AM

Arcturus

PISCES 13

10°

Altair

16 18

0°

17 12

AQUARIUS

19 19

–10°

VIRGO

OPHIUCHUS

12

14

CAPRICORNUS

TH E N I G H T S KY

–20° 19

14 19

18

17

18

18

17

19

Fomalhaut 15

14

SAGITTARIUS 13

15 16

18

LIBRA

Antares

PISCES 16

16

13

SCORPIUS Shaula

12

CETUS URANUS

N G N I R O M

S K

Y

APRIL

449

SOUTHERN LATITUDES THE STARS In the Southern Hemisphere, Crux lies almost on the north– south meridian line, with Rigil Kentaurus (see p.252) and Hadar— Alpha (α) and Beta (β) Centauri— slightly to its lower left. Antares, in Scorpius, is rising in the southeast, while Canopus, in Carina, sinks low in the southwest. Hydra’s long body meanders overhead, its head adjoining Cancer in the northwest and its tail ending between Libra and Centaurus in the southeast. Spica, the brightest star in Virgo, is high in the east. Leo lies in the north, with Arcturus, in Boötes, in the northeast. Observers north of latitude 40°S can see the Big Dipper low on the northern horizon.

background stars. On its edge is the Jewel Box cluster (see p.294), or NGC 4755, which looks like a hazy star to the naked eye. On display in Carina is the cluster IC 2602 and the Carina Nebula (see p.247), or NGC 3372. To the east, among the rich star fields of Centaurus, is the globular cluster NGC 5139 or Omega (ω) Centauri, which looks like a hazy 4th-magnitude star. In the north of the sky, members of the Virgo Cluster are well placed for telescopic observation this month.

DEEP-SKY OBJECTS Next to the Southern Cross, an apparent gap in the rich stream of the Milky Way is visible to the naked eye. This is, in fact, a dark nebula, known as the Coalsack, which obscures the light of the

THE COALSACK

This dark cloud of dust (center left), next to the Southern Cross, is silhouetted against the bright background of the Milky Way.

THE CARINA NEBULA

This huge nebula in the southern Milky Way is visible to the naked eye. Eta (η) Carinae (center, left) is a peculiar variable star, which is surrounded by a glowing shell of gas.

6PM

3PM

NOON

9PM Capella

40°

MIDNIGHT Castor

30°

GEMINI

Pollux

12 14

LEO

13 19 Aldebaran

12

Hyades Regulus

CANCER

ARIES

16

15 17

15

16

Pleiades

TAURUS

20°

18 15

12

17 13

Betelgeuse Procyon

10°

Bellatrix 0°

14 Mira Rigel

17

–10°

Spica –20°

POSITIONS OF THE PLANETS

E

V

E

N

I N

G

K

This chart shows the positions of the planets in April from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on April 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Neptune

EXAMPLES

13

Jupiter’s position on April 15, 2013

14

Mars’s position on April 15, 2014. The arrow indicates that the planet is in retrograde motion (see p.68).

T HE N I G H T S K Y

S

Y

P

M

Bete

GEM

INI GA

lgeu ix

HYA

Alde

M3 5

M

Ca sto r

Ca pe lla

se

UR TA

M 4

CA

M3

US

M1

M

ELO PAR DA

NGC

LIS

X

M 33

N LY

37

UL UM

Pollux

latr

S

AU RI

I

EU

38

ER S

TR

AN G

bara

DES n

EIA

PL DE S

N O

R

TH

36

5

Variable star

884 NGC

URS

M10 3 869

A MAJO R

C ASSIO

M81

PEIA

EDA

Open cluster

R

S NE IC CA AT N VE

L AC E R

CEPHEUS

INO

BIG THE PER DIP

URSA M Polaris

M52

NORTH

Diffuse nebula

Planetary nebula

L O O K I N G N O RT H

ANDR OM M31

Globular cluster

DEEP-SKY OBJECTS Galaxy

DR

TA

O AC

M39

BO

E OT

n De

eb

S

60°N

40°N

CO

20°N

POINTS OF REFERENCE Horizons

LIS g Ve

13

A

M

a

9

US

R LY

GN CY

M2

Date

March 15 April 1 April 15 May 1 May 15

Zeniths

O

RT

H

60°N

E

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES

N

57

Bel

E ST

4

Daylightsaving time

1am

Midnight

11pm

Ecliptic

10pm

9pm

20°N

TH E NI G H T S KY

W

3

EAST

US

CH

HIU

OP

A

UL

EC

LP

VU

o

ES

N 1

re

bi Al

ST A

M

UL

RC HE

REA

BO NA

RO 92 M

I

r

1

1 10

M5

M

iza M

ORIO 0

STAR MAGNITUDES -1

2

APRIL | NO R THE R N L AT I T UD E S

WEST

450

R SCO

S

M8

H

0

M4

S

SO

U

T

a

Had ar

5139

TAU RUS

NGC

CEN

Spic

M87

SOUTH

CRUX

CRATER

M

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

LE O

Planetary nebula

s

A

A

HY

A DR

M

67

N CA

CE

R

P

I YX

Horizons

60°N

40°N

20°N

POINTS OF REFERENCE

VELA

A NTL I

lu gu Re

C ARIN

ANS SEXT

IN 4 M4

OR

LOOKING SOUTH

Gacrux

Acrux

Becrux

A

ES

M104

IC

COR V US

64

EN

L

EO

APRIL | N OR T HE RN LAT I T UD E S

s are Ant

PIU

LU

ST

S

M5

PU

3

O

M8

RG

S

EA

LI B

RA

ECLIPTIC

VI

M

OM

UR MA SA JO R

S

M

C

PU

Zeniths

48

yo n Pro c

I

IN GE M 46

SO

PP

M

I AN

OR

IN

SM IS

TH

60°N

U

M

47

ON

M

EAST 93

2 M1 M10

C

S

RO OC E

UT M

urus Arct

S

HU 53

AN I

C OPHIU

R

W

1

Siriu

s

0

40°N

20°N

South

North

Ecliptic

STAR MOTION

ES T

E NS

P CA M5

E OT OR

BO M

MA J

SERP 3

ra

M

Adh a

BE

M4

C

WEST

451

CA

Pr oc yo n

Po l

M3

S

M

IN O

G

R lu x

M48

CA

N

44

CE R

M

M6 7

LE O

use

N 5

OS

AU

RI

G

N

A

N

S

s

OR

AT ER

THE BIG DIPPER

R T

E

A

Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

CORVUS

7

M

M8

4 10

RG

4

VI

M6

O

S

01 M1

M51

CE

53

a M

Spic Horizons

C

TI

LIP

s ru ctu Ar

EC

M3

0°

20°S

BO

E OT

S

M5

O

R

A N S RO LI CO REA BO

O AC

N

T 0°

T

H

20°S

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES Date

March 15 April 1 April 15 May 1 May 15

Zeniths

DR

S

40°S

POINTS OF REFERENCE

ENI

ar Miz

TICI VENA

ER COMA B

CANES

R URSA MINO

NORTH

M A JO R

CR

O 5

Planetary nebula

L O O K I N G N O RT H

M81

URSA

MIN

LEO

Regu lu

A XT

or

X

SE

NI

I

Ca st

LY N

DR

ER

IN

T

HY

OC M

E S

4

2

M1

Daylightsaving time

1am

Midnight

11pm

Ecliptic

10pm

9pm

40°S

TH E NI G H T S KY

MON

ORIO

H

W

3

EAST

HUS

IUC

OPH

ES

UL

RC

HE

elge 1

13

M

T

S

A

PU

E

CA

S N

PE

ER

Bet 0

STAR MAGNITUDES -1

2

APRIL | S OUTHE R N L AT I T UD E S

WEST

452

M M

la

M2

9

3

19 M

M

M2

4

M2

6

M

M2

7

8

8

2

A N LI O A R R CO ST U A

M

69

4 M5

GI SA

AR TT

IU S

S

O

U T

T

LE

S

OP

IU

SC

RP

IU M

A

IN

AR

A us

Ri Ke gil nta ur

NG

S

PAV O

TR CIR IA C IN AU N G U US ST LUM RA LE

RM

DU

NO

S 13

r

9

Hada

C5

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

PHO

A

ENIX

Planetary nebula

SMC

US

IS

NA ARI

PY

X

H

UM

s

IS

O OR

O

Horizons

0°

20°S

A

40°S

7

B

S

0°

O

ius

S

H

U

T

AN ID

U

I

M

N

LU

CA

E CA

M

ER

U OL

M4

Zeniths

C

ra

a dh

M IU

AD

G LO

R DO

u op n Ca

P

P UP

6 M4 3 M9

POINTS OF REFERENCE

r

L ICU

rna

RET

he Ac

LMC

S AN VOL OR PICT

C

VELA

IA

MENS

TL AN

HYDR

LOOKING SOUTH

SOUTH

NGC 104

OCTANS

CHAMAELEON

MUSCA

Acrux

TUCANA

A PUS

CRUX

Becrux

RA

Gacrux

US

HYD

APRIL | S O UTH ER N L AT I T UD E S

EAST

M

21

TE

S

S

s

A

ta

E

re

CO

RA

H

An

S

4

Sh au

62

PU

S

NT AU R

RV U

CE

O

M50

41 M

A

Sir

AJ OR

M

H

US

S

C HIU 80 M

U

L

W

0 M1

T

M

S

PU

OP 3

ION

20°S

40°S

South

North

Ecliptic

STAR MOTION

S

M

LE

LIB

OR

M8

E

C

WEST

453

454

MONTHLY SKY GUIDE

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

May 6 May 25 May 14 May 4 May 21 May 10 May 29 May 18

May 20 May 10 May 28 May 18 May 6 May 25 May 15 May 4 PLANETS

2014: May 10 Saturn is at opposition, magnitude 0.1. 2014: May 25 Mercury is at greatest evening elongation, magnitude 0.6. 2015: May 7 Mercury is at greatest evening elongation, magnitude 0.5. 2015: May 23 Saturn is at opposition, magnitude 0.0. 2016: May 22 Mars is at opposition, magnitude -2.1. 2017: May 17 Mercury is at greatest morning elongation, magnitude 0.6. 2018: May 9 Jupiter is at opposition, magnitude -2.1. ECLIPSES AND TRANSITS

2012: May 20–21 An annular eclipse of the Sun is visible from the northern Pacific Ocean, southern Japan, and the western United States. A partial solar eclipse is visible from northeast Asia, the northern Pacific Ocean, and western North America. 2013: May 10 An annular eclipse of the Sun is visible from the northern Australia and into the central Pacific Ocean. 2016: May 9 The transit of Mercury across the Sun is visible from North 50°

MAY As summer approaches, the days get longer in the Northern Hemisphere, restricting early evening observation, while in the Southern Hemisphere the opposite is true as the days become shorter and the nights longer. For northern observers, the Big Dipper is high up in the sky and Virgo is due south. Observers south of the equator are treated to the sight of the brilliant stars of Centaurus (the Centaur) and Crux (the Southern Cross) at their highest.

NORTHERN LATITUDES THE STARS

DEEP-SKY OBJECTS

The tip of the handle of the Big Dipper lies on the north–south meridian this month. The second star in the handle, Mizar, has a fainter companion, Alcor, which is visible to the naked eye (see p.276). The curved handle of the Big Dipper points toward orange Arcturus in Boötes, also high up. Almost due south is Spica, the brightest star in Virgo. Gemini, the last of the winter constellations, begins to set in the northwest. As it departs, the stars of summer rise in the east, led by the brilliant blue-white star Vega (see p.253) in Lyra. For those observers at lower northerly latitudes, Antares and the stars of Scorpius begin to appear over the southeastern horizon.

Two large and relatively bright galaxies are well positioned for observation in May. South of the Big Dipper’s handle is the Whirlpool Galaxy (see p.315), or M51, while to the north of the handle is M101, which is larger but less prominent. On clear nights, each appears as a faint patch of light through binoculars; a telescope is needed to see their spiral structures. The fan-shaped Coma Star Cluster is well positioned, as is the Virgo Cluster of galaxies (see p.329).

America, South America, Europe, Africa, and central Asia.

METEOR SHOWER

FINDING THE POLE STAR

The Eta Aquarid meteor shower is visible this month, but because the radiant lies virtually on the celestial equator, the shower is not seen well in far northerly latitudes.

Alpha (α) and Beta (β) Ursae Majoris, in the bowl of the Big Dipper, point toward the north pole star, Polaris (in green box).

NEPTUNE 19

URANUS 9AM

40°

19

30°

18

17

18

17

16

15

14

13

12

PISCES 16

15

14

13

1

AQUARIUS 12

ARIES 20° 12

16

CETUS

10°

17 19 13

PISCES 14

0°

Altair 17

AQUARIUS OPHIUCHUS

Mira –10°

TH E N I G H T S KY

18

19

18

15 16

16

17 19

Antares

CAPRICORNUS SAGITTARIUS

SCORPIUS Shaula

M O R N I N G

S K Y

MAY

455

SOUTHERN LATITUDES THE STARS The constellation Crux and the two bright stars in Centaurus that act as a pointer to it, Alpha (α) Centauri—or Rigil Kentaurus (see p.252)—and Beta (β) Centauri— Hadar, are high in the southern sky in May. Crux is to the west of the north–south meridian, and Rigil Kentaurus and Hadar are on the eastern side. Although Rigil Kentaurus is usually described as the closest naked-eye star to the Sun, it actually consists of two yellowish stars, which form a double star that is easily divided through a small telescope. The brightest member of the Southern Cross, Acrux—Alpha (α) Crucis— is also a double star that is divisible with a small telescope, but its component stars are blue-white. Spica, in Virgo, lies high overhead with orange Arcturus, in Boötes, in the north. Leo sinks toward the northwestern horizon, while in the southeast Scorpius and Sagittarius are coming into view—a sign that the southern winter is approaching.

DEEP-SKY OBJECTS

4th-magnitude star lying virtually on the north–south meridian this month. To the north of it lies NGC 5128, a peculiar radioemitting galaxy also known as Centaurus A (see p.322), which is one of the easiest galaxies to find with binoculars. Another bright galaxy located near the meridian is M83, a spiral galaxy that is positioned face-on to Earth. In Crux, the dark Coalsack Nebula and the sparkling Jewel Box (see p.294) remain prominent.

best seen from equatorial and southerly locations, where May nights are longer. The Eta Aquarids are caused by dust from Halley’s Comet (see p.216).

RICH STAR FIELDS

Alpha (α) and Beta (β) Centauri (left) point toward the constellation Crux (right). The Coalsack Nebula (bottom, right), most of which lies within Crux, obscures a large area of stars in the Milky Way.

METEOR SHOWER The Eta Aquarid meteor shower reaches its peak around May 5–6, when 30 or so fast-moving meteors can be seen radiating each hour from near the star Eta (η) Aquarii, located almost exactly on the celestial equator. However, this part of the sky does not rise very high until around 3 am, and the meteor shower is

3PM NOON

The largest and brightest globular cluster in the sky, NGC 5139, or Omega (ω) Centauri, appears to the naked eye as a hazy

6PM 50°

Capella

9PM

40°

Castor Pollux

MIDNIGHT

14

CANCER

14 19 18

15

15

LEO

Arcturus

12

GEMINI

30°

TAURUS 13

17

15 13

Pleiades 15

20°

Aldebaran Hyades

12 16

10°

Regulus

Betelgeuse Procyon

VIRGO 12 13

14

Bellatrix 0°

14

17

Rigel –10°

Spica

18

LIBRA

POSITIONS OF THE PLANETS

S

E V

E

N

I N

K

Y

G

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Neptune

EXAMPLES

13

Jupiter’s position on May 15, 2013

16

Mars’s position on May 15, 2016. The arrow indicates that the planet is in retrograde motion (see p.68).

T HE N I G H T S K Y

This chart shows the positions of the planets in May from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on May 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

M

x

st or

U RI G

A C

N

I NX

44

M IN ap ell a

LY

M

GE M

M

M

I M

A 38

O

CER

T

LE

OR M 36

S

Ca

lu

Po l

E

1

35

N

O

37

R T 4

5

Variable star

O R

UR SA

M

M81

C VE AN E N AT S ICI

THE BIG DIPPER

LIS

Open cluster

M51

Mizar

Polaris

1 M10

DRA

S

M31

M5

Horizons

60°N

L AC

M

39

SU

S

TA ER

GA PE

40°N

20°N

POINTS OF REFERENCE

EUS

2

CEPH

E OT

OR

BO

MIN

CO

U R SA

C AS S I O P E I A M103

Diffuse nebula

Planetary nebula

L O O K I N G N O RT H

NORTH

TRIANGULUM

ANDROMEDA

NGC 8 NGC 869 84

ELO PARD A

JO R

RS

CA

MA

PE

EUS

M34

Globular cluster

DEEP-SKY OBJECTS Galaxy

De

CY

b ne

G

N

U

S

M

O

29

N

R

T

eo 60°N

H

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES Date

April 15 May 1 May 15 June 1 June 15

Zeniths

ILA

9pm

20°N

Ecliptic

10pm

11pm

Midnight

1am

Daylightsaving time

Altair

3 M1

ES

UL RC

HE

CAN

MIN

H

W

3

EAST

A

UL

AQ U

LP

H IN

US

ITT A

SA G

DE

57 M

EC

TH E NI G H T S KY

Procyon 1

bir Al

LP

VU

27

M

T

S

A

E

Ve ga

A

LY R

92 M

CANIS

0

STAR MAGNITUDES -1

2

MAY | NO R THE R N L AT I T UD E S

WEST

456

A NS C

1 M1

M2 M

A UD

M

M

6

M

M1

7 M1 5 M2

8

M2

M2

2

23

M

21

M

4

M2

8

8

M

7

E

6

H

A

14

S T

la

M 62

M

SC

A

M 12

OR PI

es

tar

An

AR

19

10

4

80

NO

US

M

M

S

S

O

U T

PE

RM A

N

S

CIN US

S

M83

Spica

LOOKING SOUTH

SOUTH

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS

CRUX

Becrux

Open cluster

Diffuse nebula

ux Acr

US

ux Gacr

CORV

M87

Planetary nebula

M104

VIRGO

M53

M64

COMA S CE BERENI

CENTAURUS

Arcturus

M3

Hadar Rigil Kentaurus

IC

ECLIPT

RA

US

LIB

M5

T

LUP

PU

CIR

CA

IS

A

MAY | NO R THE R N L AT I T UD E S

EAST

16

au

9

M

US

Sh

M

HI

H UC Horizons

60°N

40°N

lus

S

20°N

LA

Zeniths

VE

S

I

A

TL AN

S

N TA X E

Re gu

POINTS OF REFERENCE

TER CRA

O LE

T

H

60°N

O

U

8

S

T 40°N

20°N

South

North

Ecliptic

STAR MOTION

M4

7 M6

RA

HY D

OP R

W

SERPE LE

S

HE U RC

E

SE

XI

E OT O B

PY

N RO AL O C RE BO

WEST

457

ux

M

CA

M6

ul

M

S LE

O

OR

A

M

E AT

O

AN XT us

LE

IN

UR S

CR

A

ER

N

N LY AJ OR

R

O

R T

X

g Re 5

Variable star

M8

1

C OR VU S M104

M87

M64

Open cluster

M3

rus

M101

Arctu

VIRGO

Spica

M53

ICI

M51

Mizar

BOOT

NOR URSA MI

NORTH

Diffuse nebula

Planetary nebula

L O O K I N G N O RT H

VENAT

COMA BERENICES

CAN ES

THE B IG DIPPE R

Globular cluster

DEEP-SKY OBJECTS Galaxy

SER

M

5

NA

S

PU

O

IS

T

AL

AC

RE

CA

BO

PEN

CORO

ES

DR

0°

M1

3

20°S

HE

ES

N

O

0°

R

T

H

20°S

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES Date

April 15 May 1 May 15 June 1 June 15

Zeniths

92

UL

M

RC

40°S

POINTS OF REFERENCE Horizons

LA

9pm

40°S

Ecliptic

10pm

11pm

Midnight

1am

Daylightsaving time

AQUI

SE

7

4

T

14 M

S

HU

UC

DR

NC

W

E S

T

TIC ECLIP

H

3

EAST

M1 0

HI OP

12 M

RA

LIB

HY

44

1

7

M5

SE CA RP U ENS DA

A

A

S

LY R Ve ga

E

TH E NI G H T S KY

ll Po 0

STAR MAGNITUDES -1

2

MAY | S OUTHE R N L AT I T UD E S

WEST

458

22

UM

6

ILA

EAST

G SA

IT M 55

M

IC

RO

O SC

PI

E

54

H

M

A

M

S

T

S

IN

GR

OP

US

SC

S

LE

DU

TE

7

S

O

U T

IU M

AR

A

TUC

S

ANA

A

PAV O

RM

PU

C IN US

S

Achernar

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS

LOOKING SOUTH

Open cluster

Diffuse nebula

A

S

U

R A VOL

IUM

NS

LA

DO

VE

IA

RA

TL AN

p no

DO

Ca

us

Horizons

0°

20°S

40°S

POINTS OF REFERENCE

OG HOROL

UM ICUL

C LM

INA

RA

C R AT E

D HY

A

RET

MENS

CAR

RV

Planetary nebula

ON

MUSC

ux

Gacr

CRUX

S

CHAMAELE

SOUTH

X

SMC

PHOENI

NGC 1 04

OCTANS

APU

Acrux

HYDRUS

Hadar

Becrux

RU CENTAU

TRIAN GULUM A U ST RALE

CIR

s

uru

Rig Ken il ta

NGC 5139

MAY | S OUT HE R N L AT I T UD E S

M11

RO R CO ST AU

U

4

U

69

RI

8

N A A LI S

M

TA

NO

LU

M83

CO

Zeniths

P PU

PI

S

S

U

C

0°

O

IS

PY X

M

S

M

6

la

T

H

LU

M

au

O

25 8

Sh

E

M2

S

W

M M

h

M

HU IU

Ad

1

C IU P OR

BA

es

T

tar

7

20°S

40°S

South

North

Ecliptic

STAR MOTION

S

M48

M

T M2 8 M1

93

OS

CER

A QU

ON O

SCU 3

SC

M

6 46

M2 7

H 62

ara

OP

M

M1

M4

M1

An

CA

M9

R

M2 M

AJO

M 19

NIS M

M2 4

1

M

M4

M 80

WEST

459

460

MONTHLY SKY GUIDE

JUNE

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

June 4 June 23 June 13 June 2 June 20 June 9 June 28 June 17

June 19 June 8 June 27 June 16 June 5 June 24 June 13 June 3

Northern nights are at their shortest, and southern ones at their longest, around the solstice on 21 June, the date on which the Sun reaches its farthest point north of the celestial equator. In the northern sky, Arcturus and the other stars of Boötes stand high, and the giant Summer Triangle of Vega (in Lyra), Deneb (in Cygnus), and Altair (in Aquila) lies in the eastern half of the sky. Southern observers enjoy a rich band of constellations in the Milky Way during their long winter nights.

PLANETS

NORTHERN LATITUDES

2013: June 12 Mercury is at greatest evening elongation, magnitude 0.6.

THE STARS

2015: June 6 Venus is at greatest evening elongation, magnitude -4.3.

The bowl of the Little Dipper, in Ursa Minor, stands high above the northern horizon with the sinuous body of Draco, the Dragon, winding around it. The horseshoe shape of Corona Borealis, the Northern Crown, lies on the north–south meridian with the head of Serpens, the Serpent, below it, while Arcturus, in Boötes, is high in the western half of the sky. In this area of sky, Arcturus is the base of a large Y-shaped pattern of bright stars completed by Epsilon (ε) and Gamma (γ) Boötis plus Alpha (α) Corona Borealis (also known as Alphecca). Leo is setting in the west, and Spica, in Virgo,

2015: June 24 Mercury is at greatest morning elongation, magnitude 0.6. 2016: June 3 Saturn at opposition, magnitude 0.0. 2016: June 5 Mercury is at greatest morning elongation, magnitude 0.6. 2017: June 3 Venus is at greatest morning elongation, magnitude -4.3. 2017: June 15 Saturn at opposition, magnitude 0.0. 2018: June 27 Saturn at opposition, magnitude 0.0. 2019: June 10 Jupiter at opposition, magnitude -2.6. 2019: June 23 Mercury is at greatest evening elongation, magnitude 0.6. ECLIPSES AND TRANSITS

2012: June 4 A partial eclipse of the Moon is visible from western North and South America, the Pacific Ocean, Australasia, and eastern Asia.

9AM

50° 2012: June 5–6 A transit of Venus across

the Sun is visible from North America, the Pacific Ocean, Australasia, and Asia. 40°

is low in the southwest. In the eastern sky, the bright stars Vega (see p.253), Deneb, and Altair (see p.252) mark the corners of the Summer Triangle, best seen in late summer and fall. Ruddy Antares and the stars of Scorpius twinkle low on the southern horizon— June and July are the best months of the year for far-northern observers to see Scorpius in the evening sky.

DEEP-SKY OBJECTS The brightest globular cluster in northern skies, M13, is high up on summer evenings. It can be found along one side of the Keystone of Hercules, a quadrangle of stars that forms the torso of the constellation Hercules. M13 appears as a fuzzy 6AM

30° 15

13 12

20°

These high-altitude clouds can be seen on summer nights, illuminated by the Sun’s rays that come over the horizon around midnight.

6th-magnitude star through binoculars, and it can be glimpsed by the naked eye under good conditions. It can be compared with M5, another 6th-magnitude globular cluster visible through binoculars. M5 lies in the head of Serpens and is usually regarded as the second-best northern globular cluster. Near the handle of the Big Dipper, the spiral galaxies M51 and M101 remain well positioned for observation.

Pleiades 19

ARIES

3AM

12

15

16

Aldebaran

MIDNIGHT

14 17

Hyades

10°

NOCTILUCENT CLOUDS

PISCES Altair

Bellatrix

AQUARIUS

TAURUS

0° Mira Rigel –10°

TH E N I G H T S KY

18 19

18

19 17

16

PISCES 15

14

13

18

17

19

18

CAPRICORNUS 16

15

14

Fomalhaut 13

12

11

SAGITTARIUS

12

AQUARIUS

CETUS URANUS

NEPTUNE

M O R N I N G

S K Y

Shaula

461

SOUTHERN LATITUDES THE STARS

THE SCORPION’S LAIR

Orange-red Antares, the star at the heart of Scorpius, and the curved line of stars marking the Scorpion’s tail are distinctive sights in June skies. Hovering over the “sting” in the tail are two prominent star clusters, M6 and M7 (bottom, left).

A rich band of constellations can be seen across the sky, from southwest to northeast, along the path of the Milky Way. Crux (the Southern Cross) and Centaurus (the Centaur), are in the southwest, to the right of the celestial meridian. The lesserknown constellations Lupus, Norma, and Triangulum Australe are on the meridian. Ruddy Antares (see p.256) is overhead, with the curving tail of Scorpius, the Scorpion, extending to the southeast. Next to its tail are the dense star fields of Sagittarius in the Milky Way. Along the Milky Way to the east is Altair (see p.252) in the constellation Aquila, while Vega (see p.253) is low in the northeast. Arcturus and Spica are high in the northwest.

magnificent through binoculars. M7 is the larger and brighter of the two; it appears twice the width of a full moon. Another prominent open cluster in Scorpius is NGC 6231, positioned next to Zeta (ζ) Scorpii. The globular cluster Omega (ω) Centauri, or NGC 5139, and the peculiar galaxy NGC 5128, or Centaurus A, remain well placed for observation this month, as do the Coalsack Nebula and the Jewel Box Cluster (see p.294), in Crux, and the spiral galaxy M83 (in the constellation Hydra).

DEEP-SKY OBJECTS Heading away from Scorpius and toward the Milky Way and the center of the Galaxy, two magnificent open star clusters, M6 and M7, are positioned near the end of the Scorpion’s tail. Both clusters are visible to the naked eye, and they appear

NOON 3PM

50°

6PM 40°

Castor

9PM 15

MIDNIGHT

GEMINI

Pollux

LEO

Arcturus

18

19

14

19

13

13

30° 16

17

13 20°

15

CANCER Regulus 12

VIRGO 12 13 15

16

19

17 14

–10°

Spica

14

17

10°

Procyon 0°

OPHIUCHUS

16

Betelgeuse

16

18

POSITIONS OF THE PLANETS

LIBRA

This chart shows the positions of the planets in June from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on June 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

SCORPIUS

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Neptune

EXAMPLES

N G N I E E V

S K

Y

13

Jupiter’s position on June 15, 2013

16

Mars’s position on June 15, 2016. The arrow indicates that the planet is in retrograde motion (see p.68).

T HE N I G H T S K Y

Antares

CA

u Reg

X

UR

SA

lus

LEO

VE 51

M8 1

TI NA

CI

O Cap ella

TH DI E BI PP G ER

M

l Po

GE

R

M

lu

IN

x

4

r

N

O

R T

M

3

4

5

Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

OT ES

10 1

BO

M

D R AC O

R DA L I S

Polaris

URS A MINOR

Open cluster

Diffuse nebula

ES

EU

S

EI A

NG

UM

2

UL

M5

Vega

M57

o

Horizons

60°N

40°N

39

31

M

M

20°N

POINTS OF REFERENCE

TRI A

IOP

CEPH

CASS

NGC 869 M103

NGC 884

M34

Planetary nebula

L O O K I N G N O RT H

NORTH

PERSEUS

CAMELOPA

iza

I 8

IGA

AJ OR

M3

AU R

M

6

ES

IN

LY N

M 37

M3

CAN

or

T

M

M4

S

Ca st

E

O

ER

H

W

LE

NC 1

A RT

DR

O

N

O

R

T

H

S

LEU

US Date

May 15 June 1 June 15 July 1 July 15

60°N

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES

AN

CE LA

M27

Zeniths

Daylightsaving time

1am

Midnight

11pm

Ecliptic

10pm

9pm

20°N

EAST

5

M1

ULA

EC LP 29

UU

EQ

S

SU

PE GA

T

S

A

DEL A ED M

b

VU M

Albire ne De

US

GN CY

A

LY R

92 M

UL

RC HE

PH IN

E

TH E NI G H T S KY

M67

0

STAR MAGNITUDES -1

2

JUNE | NOR THE R N L AT I T UD E S

WEST

462

UI AQ

CAP

T

LA

S

r ltai

M

O RIC

RN

US 55

G SA

AR ITT

IU S

A

M

26

E

M

54

11

M

M

C AU

M 69

25

O ST R O N RA A LIS

22

M

LE

28

21

OP

7

SC

M

M8

M

M 6

M

9

A

S

2

S M1

res M4

SER

ONA BOREAL

S

O

U T

SOUTH

CIRCINUS

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

B

s

3 M

tu

ru

IC

S TE OO

Planetary nebula

ar Had

3

ux

M

87

4 10

M

VU OR

S

Horizons

60°N

40°N

20°N

POINTS OF REFERENCE

x

C

ru ac G

S

13 9

GO

C5

RU

r Bec

TAU CEN

NG

M8

VIR

C R BE

O E MA N IC ES

64 M

ica

Sp

53 M

Ar c

IPT ECL

Rigil rus Kentau

LUPUS

LIBRA

LOOKING SOUTH

TRIAN G AUSTR ULUM ALE

NORMA

IS

M5

PENS CAPUT

COR

RPIUS

M80

2

SCO

Anta

M1 0

HU

M1 9

UC

M6

HI

la

Sh au

M

OP

AR

14

IUM

23

A

M

CA UD

M 1 M 6 17 M 18 M 24

TE

M

M

TU

JUNE | NO RT HE R N L AT I T UD E S

EAST U SC

H

A

S Zeniths

E AT R C

LE

O

S

Y

U

T

60°N

O

H

H

R

RA

SE N

D

TA GIT

LA E RP

W

CU E

T

S 40°N

20°N

South

North

Ecliptic

STAR MOTION

S

PE VUL UL

E

H

C ER S

SA 3

EX TA N

M1

WEST

463

S g Re ulu s

LE

CA

M 87

4

C

M 64

M5 3

O

ES

RG

NIC

O M IN M5

ru s

ctu

Ar

M3

1

Miza r

SE

M101

BO

OR

N

O R

T Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

M5

D R AC O

MINOR

NORTH

Diffuse nebula

3

H

S

2

Horizons

0°

ga Ve

R LY

20°S

A

TUM

M26 57

LP

EC

S

CY

EU

U

G

N

o

O

ire lb A

N

0°

SA

R

T

H

20°S

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES Date

May 15 June 1 June 15 July 1 July 15

Zeniths

PH

M

CE

40°S

VU

SCU

M11

POINTS OF REFERENCE

M9

LE

I

CU

OP

HER

M1

Planetary nebula

L O O K I N G N O RT H

U R SA

COR ONA BOREALIS OTE S

RP ENS CA PUT

RA

OM A

B ER E

VI

VE

NA T ICI

ica

LE

M

NE S

A R

Sp

O 5

Daylightsaving time

1am

Midnight

11pm

Ecliptic

10pm

9pm

40°S

TH E NI G H T S KY

U

RS

AJ O

T H E D IP B I G PE R

LIB

T

TIC

S

4

EAST

M16

SE CA RPE UD NS A

S

LEU

UU

EQ

US

14 M

M10

W E

ECLIP

H

3

air

TA

T

HIN

LP

DE

Alt

G

IT

27

10 M

N TA 1

S

M

29

b

S

M

De

ne

A E

LA AQ UI

LA

U

US CH

U

12 M

SEX 0

STAR MAGNITUDES -1

2

JUNE | S O UTHE R N L AT I T UD E S

WEST

464

AQU S

R

AR

IUS M

P CA

RI

C

N OR

M

PIS

CI

EAST

30

TR US A S

I IC

R

T

55

S

M

OE

R TA

U

S NU

SC

ut

m Fo

a alh

PH

NI X

TE

CA

L TU

P UL

TO

S

O

A

U T ER

I DA

r

NU S

NGC 10 4

erna

Ach

NA

AR

PAVO

UM

M6

US

PI

la

S

HYDRUS

LOOKING SOUTH

SOUTH

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

NG

C5

A

PIC

op

A

us

RIN

n Ca

R TO

CA

VE

Horizons

0°

20°S

40°S

POINTS OF REFERENCE

ADO

NS

x

Acru

DOR

Planetary nebula

M

US

rux Gac

VOLA

MUSC

CRUX

Becrux

M83

13 9

UR CENTA

LMC

U RE TICUL

M E N SA

CHAMAELEON

APUS

HOROLOGIUM

SMC

OCTANS

Hadar

Rigil Kentaurus

S

CIRCINUS

TRIANG ULUM AU ST R A L E

MA

PIU

NOR

OR

LUPU RA Zeniths

LA

ATE R

TL AN

U

0°

O

P

S

PU

I

CR

T

A

A BR

JUNE | S OU THE R N L AT I T UD E S

A

T GI SA S

R CO ST AU DU

7

CO

au

GR

4 M5

IN

9

M

M6

IU

8

OP

M

ES

Sh

E

SC

2

S

62

H

O

IU

SC

LI RVU S

CO

M2

O RA NA LI S

M8

YD

M9

H

M

P

9 M1

IS

M2

s

H

NS XTA 20°S

40°S

South

North

Ecliptic

STAR MOTION

S

re

E

ta

W

S

M25

4

XI

M 17

SE

3 M2 1 M2 M 18 M24

An

PY

M

T

M80

WEST

465

466

MONTHLY SKY GUIDE

JULY

SPECIAL EVENTS PHASES OF THE MOON FULL MOON

July 19

2013 July 22

July 8

2014 July 12

July 26

2015 July 2, 31

July 16

2016 July 19

July 4

2017 July 9

July 23

2018 July 27

July 13

2019 July 16

The strong man of Greek mythology, Hercules, lies overhead as seen from mid-northern latitudes, between the bright stars Vega (in Lyra) and Arcturus (in Boötes). South of Hercules is another large constellation, Ophiuchus, which represents a man encircled by a serpent, Serpens. In southern skies, the Milky Way passes overhead from the southwest to the northeast. The zodiacal constellations Scorpius and Sagittarius stand high in the Milky Way’s richest part.

NEW MOON

2012 July 3

July 2

NORTHERN LATITUDES

PLANETS

2012: July 1 Mercury is at greatest evening elongation, magnitude 0.5.

THE STARS

2013: July 30 Mercury is at greatest morning elongation, magnitude 0.3.

Overhead lies Hercules, which is a large but not particularly striking constellation. Its most distinctive feature is a quadrangle formed by four stars, called the Keystone. North of Hercules lies the lozenge-shaped head of Draco, the Dragon. Between Draco and the north celestial pole is the bowl of the Little Dipper, in Ursa Minor. Arcturus, in Boötes, remains prominent in the western sky. Spica, in Virgo, is lower in the southwest, and the Big Dipper dips low in the northwest. In the eastern half

2014: July 12 Mercury is at greatest morning elongation, magnitude 0.3. 2017: July 30 Mercury is at greatest evening elongation, magnitude 0.4. 2018: July 12 Mercury is at greatest evening elongation, magnitude 0.5. 2018: July 27 Mars is at opposition, magnitude -2.8. 2019: July 9 Saturn is at opposition, magnitude 0.1. ECLIPSES

2018: July 13 A partial eclipse of the Sun is visible from southern Australia. 2018: July 27 A total eclipse of the Moon is visible from South America, Europe, Africa, Asia, and Australia. 2019: July 2 A total eclipse of the Sun is visible from south Pacific, Chile, and Argentina. A partial solar eclipse is visible from south Pacific and South America.

9AM

of the sky, the stars of the Summer Triangle climb ever higher, while the Square of Pegasus appears closer to the eastern horizon. Low in the south are the rich constellations Scorpius and Sagittarius. This is the best month for northern observers to see the two most southerly zodiacal figures in the evening sky.

good binocular sights. The globular clusters M13, in Hercules, and M5, in the head of Serpens, remain well positioned this month.

DEEP-SKY OBJECTS Ophiuchus, the large constellation between Hercules and Scorpius, contains numerous globular clusters, although only two of them, M10 and M12, are of any note. The most impressive deepsky objects in Ophiuchus are the open clusters IC 4665 and NGC 6633, both

2019: July 16 A partial eclipse of the Moon is visible from South America, 50°Europe, Africa, Asia, and Australia.

THE SUMMER TRIANGLE

Deneb (left), Vega (top), and Altair (right) form a prominent triangle that remains visible well into fall in northern skies.

6AM

40° Castor

3AM

GEMINI

30°

15

TAURUS 13

20°

19

13 14

Pleiades

14

ARIES

12 17 12 Aldebaran Hyades

13

MIDNIGHT

PISCES

10°

Altair

Betelgeuse Bellatrix 0° Mira Rigel

AQUARIUS

TH E N I G H T S KY

–10°

19

18

17

16

PISCES 15

14

13

19

18 18

17

16

15

14

Fomalhaut 13

12

12

CAPRICORNUS

1

SAGITTARIUS

AQUARIUS

M CETUS URANUS

NEPTUNE

O

R

N

I N

G

S K Y

JULY

467

SOUTHERN LATITUDES THE STARS The curved tail of Scorpius and the asterism known as the Teapot, formed from the main stars of Sagittarius, are virtually overhead for southern observers. The Milky Way is particularly dense and bright toward Sagittarius and Scorpius because this is the view toward the center of the Galaxy. Alpha (α) and Beta (β) Centauri—Rigil Kentaurus (see p.252) and Hadar—are in the southwest, pointing down to Crux, the Southern Cross. Spica (in Virgo) is in the eastern sky, Arcturus (in Boötes) in the northwest, and Vega (see p.253) in Lyra, is in the north. Altair (see p.252), in Aquila, is high in the northeast, and observers about 30°S or closer to the equator can see Deneb, in Cygnus, low in the northeast. In the southeast, 1st-magnitude Fomalhaut, in Piscis Austrinus, enters the scene.

TOWARD THE CENTER OF THE GALAXY

The center of the Galaxy cannot be seen directly, because it is obscured behind the dense Milky Way star fields of Sagittarius and Scorpius. The exact center is thought to be marked by an intense radio source called Sagittarius A* (boxed).

DEEP-SKY OBJECTS Sagittarius is well stocked with outstanding deep-sky objects, among them the 5th-magnitude globular cluster M22, which is visible to the naked eye

POSITIONS OF THE PLANETS

This chart shows the positions of the planets in July from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on July 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

under good conditions. The Lagoon Nebula (see p.243), or M8, an elongated gas cloud containing the star cluster NGC 6530, can be seen well through binoculars. To the north, in Serpens Cauda, the tail of the Serpent, lies the cluster M16—visible through binoculars— embedded in the much fainter Eagle Nebula (see pp.244–45). Other famous deep-sky objects in Sagittarius, such as the Trifid Nebula, M20 (see p.246), need to be seen through a telescope. However, one particularly bright patch of the Milky Way, M24, is prominent to the naked eye. In adjoining Scorpius, the bright open clusters M6 and M7 remain high in the sky.

METEOR SHOWER The Delta Aquarids, the best southern meteor shower, is active in July and August, reaching a peak around July 29. At best, perhaps 20 meteors an hour can be seen radiating from the southern half of Aquarius, but they are not particularly bright. NOON

3PM

50°

Neptune 40°

EXAMPLES

13

18

Jupiter’s position on July 15, 2013

Mars’s position on July 15, 2018. The arrow indicates that the planet is in retrograde motion (see p.68). Pollux

Arcturus

9PM

MIDNIGHT

19

LEO 15

Regulus

16

12

VIRGO

OPHIUCHUS

12 13

18

17

16 19

18

SCORPIUS Shaula

S K Y

15

18

20°

12 10°

CANCER Procyon

0°

17 –10°

Spica

16

LIBRA

Antares

E V E N I N G

14

18 17

13

17

T HE N I G H T S K Y

19

15

14

16 14

30°

BER

M 64

MA CO ICES EN

O

R

T

M5

S

7

LY N

X

M81

M101

Miz ar

T E H DIP BIG PER

1

TE O

A

A N N AT ES IC I

C VE

UR S

M3

M AJ OR

MI NI

LE

N

O

R sto r

GE Ca

BO

M

IN

W E

S

T 4

5

Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

D R AC

O

M9 2

OR

HERCULES

U R SA MIN

Polaris

AURIGA M38

NORTH

Diffuse nebula

R LY

A

G

EU

S

C AS

M

52

IA

SEU

S

03 M1 69 C8 NG

PE

884

SIO

NGC

PER

Horizons

60°N

LA

40°N

4

AN

M3

DR

20°N

POINTS OF REFERENCE

S DALI

PH

CY

CE

CAMELOPAR

Capella

Planetary nebula

L O O K I N G N O RT H

Open cluster

OM

A ED M31

IE

TR

AR

IA

G

U

O

N

N

R

T

60°N

H

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES Date

June 15 July 1 July 15 August 1 August 15

Zeniths

Daylightsaving time

1am

Midnight

11pm

Ecliptic

10pm

9pm

20°N

EAST

TH E NI G H T S KY

O

H

3

ES

PISC

S

SU

PE GA

M

RT A

CE

9

b

M2

De

ne 9 M3

S U N

M8

O 1

M LU

33

T

S

A

E

S

LE 0

STAR MAGNITUDES -1

2

JULY | NO R THE R N L AT I T UD E S

WEST

468

S SU

U AQ

I AR

U M 30

IS S SC U PI RI N ST AU

S

O

U T T

SC

OP IU

M

S

IN

DU

S

IC

M5 5

SA GIT

IPT

IL

TAR I

Q U

A

TA

U

M54

M69

M25

UM

M22

UT

6

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS

M19

M62

Open cluster

Diffuse nebula

S

M1

2

Planetary nebula

N RO AL O C RE BO

SE

RP

B

A

IS

S

T

LU

S PU

RA

5

LIB

M

CA

OO TE S EN

Ar c

tu

s

C

ru

Horizons

60°N

40°N

20°N

Zeniths

US

S

D HY

BE COM M53 R A E NI CE S UR TA N E

POINTS OF REFERENCE

MA

M4

NOR

M80

res

Anta

HUS

0 M1

LE

OPHIUC

Shaula

M6

M9

SOUTH

ARA

M7

M21

M8

M23

M14

HE

13

U RC

M

LOOKING SOUTH

PAVO

OPIUM

M28

M 17 M 18 M24

M16

SER CAUPENS DA

CO AUS RONA TRA LIS TELES C

US

SC M2

LA

M1 1

EC

JULY | N OR T HE RN LAT I T UD E S

EAST S

S

2

A

M

RO

U

IC

LE NU

S

E

U EQ

U A

H

M

5

OR

NU

IC

I PH ta ir

ECL

Al

PR

L IT

CA

DE S

G SA PU

27

H

60°N

O

U

RA

T

83

M1

LP M

M

O

RG

VU

VI

S NU ica

o Sp

GA PE re

W

bi

T

Al M1 04

40°N

20°N

South

North

Ecliptic

STAR MOTION

S

57

E

G A

C

M

S

CY R LY OR VU

ga Ve

WEST

469

M

GO BO

OT ES

Ar ctu r us

SE

RP

M5

RO N

EN S

CO

CA

PU

AB

T

OR EA

LIS

M

M 13

O

12

PH IU

M14

ULES

M2

3

NI

CE ES I N TIC CA NA VE

NORTH

M92

HERC

CHU S

9

RE M 3

M 51

M1 01

M

64

M AJ OR za r

Mi

DR

10

BE

N

S

O

R T

U 3

4

5

Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

M 16

17

LYRA Vega

M5

UI

A

LA

UL

S

eo bir Al

NU

Horizons

0°

ir

9

A TT 27

GI

ta Al

SA

M

M2

DE

b ne De

20°S

H

I

39

LP

M

40°S

POINTS OF REFERENCE

S

CYG

EC

AQ

LP

7

VU

11

S

M

Planetary nebula

CEPHEU

S EN S E R P DA CAU

M

25 M

L O O K I N G N O RT H

URS A MIN OR

AC O

M

A

RS A

S

RA

M

H

W E

T

LIB

CO 2

US Date

N

A RT

June 15 July 1 July 15 August 1

O

R

0°

T

H

20°S

8 pm

9 pm

10 pm

11 pm

Midnight

Standard time

OBSERVATION TIMES

CE LA

M2

August 15

Zeniths

9 pm

40°S

Ecliptic

10 pm

11 pm

Midnight

1 am

Daylightsaving time

S

RIU

TH E NI G H T S KY

M 53

VIR

87

1

EAST

M

0

STAR MAGNITUDES -1

S

AQ UA

A

ED

SU

OM

DR

PE GA

AN

T

S

A

E

15 M

LE EQ UU

S U

N

M TU

CU

26 M

M M2 18 4

JULY | S OUTHE R N L AT I T UD E S

WEST

470

UA AQ

RI

S S CI U PI S RI N ST AU m Fo

SC

EAST

P UL TO

R

S

O

U T ER

X

LO G

US

RO

ID AN

HO

IU

IUM

US

NGC

ANA

IND

TUC

M

ar

ern

OP

Ach

SC

ICUL

COPIU

UM

M

M E N SA

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS

tar

O

Open cluster

es

NO

R

Diffuse nebula

RM

Planetary nebula

pus Cano

MUS

S

ux

CR

51

UX

rux

c Ga

C NG

39

C

Horizons

0°

20°S

83

40°S

VE

Spica

US

Zeniths

LA

UR TA N E

POINTS OF REFERENCE

INA

ux

Acr

cr Be

dar Ha

CAR

CA

EON NS VOLA

PICTOR

PU

s il Rigntauru Ke

NUS

A

LU

O RG

VI

S

0°

O

U

T

H

4 M10

0 M8

CIRCI

CHAMAEL

APUS

LOOKING SOUTH

SOUTH

DORADO

LMC

SC

An

UM GUL N A I R E T RAL AUST

la

Shau

ARA

OCTANS

PAVO

LES

US

TE

HYDR

SMC

S

RE T

104

U

M6

JULY | S O UTH ER N L AT I T UD E S

US

T

ut

S

ha

al

A

0

NI

RO

S

E

M3

OE

NU

US

IC

RI

C M7 AU OR ST O N RA A LIS

19 M

62 M

A BR

LI

4 M

S U PI

S RV U

ECLIPTIC

TA

H

PH

GR

M

R ICO

IT M

G SA

CO

55

E

M

54

W

M

H

PR 69

R 20°S

40°S

South

North

Ecliptic

STAR MOTION

S

CA M

RA

2

YD

28

IA

M

AN TL

M2 8

T

M

CR AT E

M21

WEST

471

472

MONTHLY SKY GUIDE

AUGUST

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

August 2, 31 August 21 August 10 August 29 August 18 August 7 August 26 August 15

August 17 August 6 August 25 August 14 August 2 August 21 August 11 August 1, 30

The Summer Triangle formed by the bright stars Vega (in Lyra), Deneb (in Cygnus), and Altair (in Aquila) lies on the north–south celestial meridian in the northern sky this month. The cross-shaped figure of Cygnus, the swan, stands out against the background of the Milky Way, which passes overhead in mid-northern latitudes. In the southern sky, the rich Milky Way star fields in Sagittarius and Scorpius, toward the center of the Galaxy, remain well placed for observation.

PLANETS

NORTHERN LATITUDES

2012: August 15 Venus is at greatest morning elongation, magnitude -4.3.

THE STARS

2012: August 16 Mercury is at greatest morning elongation, magnitude 0.3.

Ophiuchus remain well placed in the southwest, and Arcturus, in Boötes, is lower in the west. In the east, the Square of Pegasus leads the stars of fall into view.

Blue-white Vega (see p.253), in the constellation Lyra, is the first bright star to appear overhead as the sky darkens on August evenings. Next to Lyra is Cygnus, popularly known as the Northern Cross. The star at the head of Cygnus, Albireo, is a beautifully colored double star, easily divided by the smallest of telescopes. South of Cygnus is Aquila, the Eagle, from where the Milky Way continues, via Scutum, toward Sagittarius and Scorpius in the southwest. Hercules and

2016: August 16 Mercury is at greatest evening elongation, magnitude 0.3. 2018: August 17 Venus is at greatest evening elongation, magnitude -4.4. 2018: August 26 Mercury is at greatest morning elongation, magnitude -0.1. 2019: August 9 Mercury is at greatest morning elongation, magnitude 0.3. ECLIPSES

2017: August 7 A partial eclipse of the Moon is visible from North and South America, Europe, Africa, and Asia. 2017: August 21 A total eclipse of the Sun is visible from North Pacific, USA, and South Atlantic. A partial solar eclipse is visible from North America and northern South America.

the easiest such object to see through binoculars. Another celebrated planetary nebula, the Ring Nebula (see p.257) or M27, in Lyra, can be found with a telescope. The Wild Duck Cluster, or M11, in Scutum is a 6th-magnitude open cluster visible through binoculars.

DEEP-SKY OBJECTS The August skies are stocked with deep-sky objects for northern observers. The Milky Way is divided by a dark dust cloud known as the Cygnus Rift, which extends southwestward from Cygnus into Ophiuchus. South of Cygnus, in the obscure constellation Vulpecula, is the planetary nebula M27, popularly known as the Dumbbell,

9AM

2018: August 11 A partial eclipse of the Sun is visible from northern Europe and northeast Asia.

METEOR SHOWER The year’s top meteor shower, the Perseids, reaches a peak around August 12, although some activity can be seen for a week or so on either side of this date. Perseid meteors are bright: at best, an average of one a minute can be seen streaking away from northern Perseus. Most Perseids are seen after midnight, because Perseus does not rise high before then.

6AM

Capella

3AM 50°

Castor

40° 15 30° 15 20°

18

14

14

TAURUS 13

19

MIDNIGHT

GEMINI

Pollux

13

17

Pleiades

12

12

12

Aldebaran Hyades

17

CANCER

PISCES

Betelgeuse Procyon

Bellatrix

AQUARIUS

0° Mira Rigel

TH E N I G H T S KY

–10°

19

18

19 17

16

PISCES 15

14

13

18

17

16

15

Fomalhaut 14

13

12

AQUARIUS PERSEID METEORS

Mild nights in mid-August are ideal for lying outside and watching members of the Perseid meteor shower flash across the northern sky.

CETUS URANUS

NEPTUNE

12

1

AUGUST

473

SOUTHERN LATITUDES THE STARS

celestial meridian earlier in the year, such as the Lagoon Nebula (see p.243), M22 in Sagittarius, M16 in Serpens Cauda, and M6 and M7 in Scorpius. In addition, this month southern observers can see the Wild Duck Cluster (M11) in Scutum and, looking north of the equator, the Dumbbell Nebula (M27) in Vulpecula, and the Ring Nebula (M57) in Lyra (see p.257).

Sagittarius and its Milky Way star fields remain high overhead, with Scorpius to the southwest of it. Alpha (α) and Beta (β) Centauri— Rigil Kentaurus (see p.252) and Hadar—are low on the southwestern horizon. To the north are Altair (in Aquila), Vega (in Lyra), and Deneb (in Cygnus), the stars that form the northern Summer Triangle—this is the best time of year to see them in the evening sky from southern latitudes. The Square of Pegasus is rising in the northwest. Fomalhaut, in the constellation Piscis Austrinus, is high in the east, with Achernar, in Eridanus, lower in the southeast. The Small Magellanic Cloud (see p.311) is visible midway between Achernar and the south celestial pole.

DEEP-SKY OBJECTS

THE LAGOON NEBULA IN SAGITTARIUS

The best deep-sky objects to view in the southern sky on August evenings are those that passed the

Among the dense star fields of the Milky Way lies the Lagoon Nebula (bottom, right), also known as M8, in Sagittarius (right).

POSITIONS OF THE PLANETS

This chart shows the positions of the planets in August from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on August 15. Mercury is shown only when it is at greatest elongation (see p.68) – for the specific date, refer to the table, left.

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

SAGITTARIUS

The Teapot asterism (bottom), formed by eight stars in Sagittarius, is a familiar pattern in summer skies.

Neptune

NOON

EXAMPLES

13

40°

3PM

Mars’s position on August 15, 2018. The arrow indicates that the planet is in retrograde motion (see p.68).

18

Jupiter’s position on August 15, 2013

30°

MIDNIGHT 6PM 20°

9PM

19

LEO

Arcturus

15 16

Altair 13

19 Regulus

10°

16 16 0°

OPHIUCHUS

VIRGO

CAPRICORNUS

13 14 15

18

19

18

19

17

16

SAGITTARIUS Shaula

SCORPIUS

E V E N I N G

S K Y

14

18 –10°

Spica

LIBRA

T HE N I G H T S K Y

Antares

16

18

12 17 12

ct

L

M 51

UL

ES M1 01

S Miz ar

CE TH E DIP BIG PER

M9

4

S

N

O

R T

3

U

RS A

LYN X

2

Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

LY

AC

RA

DR

M

O

INOR

M81

CY

GN

Polaris

NORTH

U

S

S

ELO

EU

b

ne

PH

De

CE

CAM

L O O K I N G N O RT H

Open cluster

Diffuse nebula

Planetary nebula

LI

IO

S

SS

DA

CA

R PA

P

M

C

88

4

3 10 GC N

NG

86

a ell

7

IGA

p Ca

R AU

M3

A 60°N

9

PE

EU

36

38 M

M

RS

40°N

S

20°N

POINTS OF REFERENCE Horizons

34

Date

T

G

R

N

O

IA

N

TR

July 15 August 1 August 15 September 1

60°N

September 15

Zeniths

H

Standard time

Daylightsaving time

9pm

20°N

Ecliptic

10pm

11pm

Midnight

1am

40°N

8pm

9pm

10pm

11pm

Midnight

OBSERVATION TIMES

M

S SU PE GA

Vega

3

M

NI

RS A M

AJ OR

M1

E OT

M6

RE

U

OR

RC

BO

53

BE

M IN

VE CAN N AT ES IC I

EO

T

5

9 M3

HE

us

S

NA RO IS CO EAL R BO

ur

W E

4

TH E NI G H T S KY

Ar

H

3

EAST

M

MA 1

S

IE

ES

T

S

DE

SC

PI

S

A

U

AR

EIA

S

PL

RU

M

3 M3

LU

TA U

E

31 M

ED

OM DR

N

A

CE

RT A A

EI

LA 52 M

CO 0

STAR MAGNITUDES -1

2

AUGUST | NO R THE R N LAT I T UD E S

WEST

474

EAST U

PH

N OE

E

A

IX

H

AR

S

R

T

PT O

L

S

O

U T

S

t

al ha u

IU

PI

SC IS

GR

TR

US

AU S

INU S

0

RN

US

INDU

IUM

US

COP

ICO

ROS

PR

MIC

M3

CA

2

LE

15

S

LP HI

7

M22

M69

M25

M

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

4 M1

M28

A

M6

Sh

au

la

OP 10

M9

M

C HIU

S M

12

2

R NO

M6

M

Horizons

60°N

40°N

20°N

A

SC

IU

S

SE

Zeniths

P OR

4

80

M

M

es 9 ar M1 Ant

HU

POINTS OF REFERENCE

AR

M7

M8

M21

M 16 M 17 M 18 M 2 3 M24

S PEN SER DA U CA

A CORONLIS A AUSTR OPIUM TELESC

M54

LOOKING SOUTH

SOUTH

PAVO

M55

M26

M11

LA

SCUTU

A

SAGITTARIUS

IPTIC

AQ U I L

A CU

57 M

E VULP

ireo

Alb

SAG ITTA

Altair

S

ECL

NU

M2

US

S

LE

RC U E

H

GN

R

S

T

H

60°N

O

BR

U

LI

S

LY R

AUGUST | NOR TH E R N L AT I T UD E S

US Fo m

Q U

M

EQ UU

M

DE

CY

C S

PE N

M5

T AP U

A

CET

SC

PU

A

LU

S CE

W

S S

T

PI

U

GO 40°N

20°N

South

North

Ecliptic

STAR MOTION

S

S GA E P

E

9

VIR

M2

WEST

475

SE PU

T

H

U

M24 M1

M

8

25

DA

M1 7

TU

M

PE

16

M

SC M

M

V

UIL

O BO

C

M5

S

CA NS 14

M M57

A

CAP

OR

NU

S

EQ

E OT

N

CA

P

U

O

S

R T Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

Planetary nebula

U

M39

L AC

Horizons

0°

2

TA ER

M5

20°S

CA

SS

IO

40°S

POINTS OF REFERENCE

US

LE

US

UU

HIN

eb

CEPHE

Den

DELP

RIC

M29

M27

Altair

SAGITTA

CYGNUS

CULA

o

Albire

UL PE

AQ

11

26

O Vega

R

NORTH

L O O K I N G N O RT H

LYRA

URS A MI NO

ULE S

O

RC

AC

2

HE

HU S

10

C

M

IU

M 13

M9

DR

SER

2

EN A

M1

RP RE LI S

5

ED

O

OM

U

DR

AS

AN

G PE

IA

N

A

R

T

H

20°S

8 pm

9 pm

10 pm

11 pm

Midnight

Standard time

OBSERVATION TIMES Date

July 15 August 1 August 15 September 1

0°

September 15

Zeniths

PE

S

S

IU

AR U AQ

RG

us 4

S

VI O

T

BO

S

A

E

N

W

RO

H

3

Daylightsaving time

1 am

Midnight

11 pm

Ecliptic

10 pm

9 pm

40°S

EAST

S

CE

PIS

TH E N I G H T S KY

tur 1

T

S

A

E

31 M

M2

15 M

Arc 0

STAR MAGNITUDES -1

2

AUGUST | S OUTHE R N LAT I T UD E S

WEST

476

H

CE

TU

ER

S

F

N OR

AX I

T

U

S

N DA

A

T RO

M

OE

IU

PH

LO G

R

DO

ern ar

S

RA

Ach

X

DO

NI

t

S

S

O

U T

RE TIC

ULU

s

opu

Can

M

A

M E N SA

SOUTH

CARINA

VOLANS

CHAMAELEON

LOOKING SOUTH

PICTOR

IUM ARA

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

C MUS

CI

S

U

ux

dar Ha

Acr

A

LU

M

PU

VE

x

LA

CR

cru Be

cru Ga

S

UX

il rus Rig ntau Ke

S

R NO

PI

NU RCI

R CO

M80

x

Horizons

0°

20°S

40°S

POINTS OF REFERENCE

A

UM GUL T RI AN R ALE AUST APUS

O PAV

TELESCOP

OPIUM

CORONA S AUSTRALI

9

M19

S

2

M6

M4

s

M9

62 M

4

An

tare

M2

M5

la

S SAGITTARIU

M55

OCTANS

US

R OSC

IND

M IC

US

LMC

RN

C

SM

104

CAN

RUS

NGC

TU

US

HYD

GR

CO

C

39

S

0°

T

S

U

RU

O

U TA N E

51

Zeniths

C

NG

ECLIPTIC

83

M23

au

7 M

6 M

Sh

RA

LIB

M 28 M 8 M21

AUGUST | SO UT HE R N L AT I T UD E S

EAST HO

O

au

E

S

LP

H

M

S CU

H

RIU alh

W

RA

UA AQ m Fo

T

IS SC I NU I P R ST AU 20°S

40°S

South

North

Ecliptic

STAR MOTION

S

I

E

30

YD

GO VIR

M

a

PR Spic

CA

WEST

477

478

MONTHLY SKY GUIDE

SEPTEMBER

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

September 30 September 19 September 9 September 28 September 16 September 6 September 25 September 14

September 16 September 5 September 24 September 13 September 1 September 20 September 9 September 28

Northern nights grow longer as the Sun approaches the celestial equator, but in the southern hemisphere the nights shorten. On September 22–23, the Sun lies on the celestial equator, and day and night are of equal length worldwide. The rich band of constellations along the Milky Way, from Cygnus in the north to Sagittarius and Scorpius in the south, begins to give way this month to fainter constellations, many of them with watery associations, such as Capricornus, Aquarius, and Pisces.

PLANETS

NORTHERN LATITUDES

2013: September 20 Venus and Saturn are 3.5° apart in the western evening sky.

THE STARS

2014: September 21 Mercury is at greatest evening elongation, magnitude 0.1.

Cepheus, high up in the north, is best placed for evening observation this month and next. Its most celebrated star is Delta (δ) Cephei, the prototype of a class of pulsating variables. Deneb in Cygnus, Vega (see p.253) in Lyra, and Altair (see p.252) in Aquila, the stars of the Summer Triangle, remain high in the western half of the sky, while the Square of Pegasus is high in the east with Cassiopeia between it and the north celestial pole. The bright star Fomalhaut (see p.253) in Piscis

2015: September 4 Mercury is at greatest evening elongation, magnitude 0.3. 2016: September 28 Mercury is at greatest morning elongation, magnitude -0.4. 2017: September 12 Mercury is at greatest morning elongation, magnitude -0.2. ECLIPSES

2015: September 13 A partial eclipse of the Sun is visible from southern Africa and parts of Antarctica. 2015: September 28 A total eclipse of the Moon is visible from the Americas, Europe, and Africa. 2016: September 1 An annular eclipse of the Sun is visible from the Atlantic Ocean, central Africa, Madagascar, and the Indian Ocean.

Austrinus is low in the south with Aquarius above it. A cascade of faint stars suggests the flow of water from the water carrier’s urn toward the southern fish, Piscis Austrinus. For observers at high northern latitudes, this is the best time of year to see the zodiacal constellation Capricornus in the evening sky, lying low in the south to the right of Fomalhaut.

DEEP-SKY OBJECTS

the North America Nebula, on account of its shape. Under clear, dark skies, it can be detected with binoculars, but it is best seen on long-exposure photographs. Another object of note in Cygnus is the open star cluster M39, which is visible through binoculars. The 6th-magnitude globular cluster M15, also visible through binoculars, is not far from the star Enif—Epsilon (ε) Pegasi—which marks the horse’s nose in Pegasus.

Near Deneb in Cygnus lies one of the most distinctive nebulae in the sky, NGC 7000, popularly called

URANUS 19

6AM 9AM 3AM

18

17

PISCES 16

15

14

13

12

Capella

CETUS

Castor 30°

GEMINI

Pollux

13

20°

LEO 10°

17

19 16

15

17

14 17

Regulus

15

14 15

TAURUS

13

12

12

Pleiades

ARIES

Aldebaran

CANCER

Hyades

PISCES

Betelgeuse Procyon

Bellatrix

0° Mira Rigel

–10°

M O R N I N G

TH E N I G H T S KY

–20°

–30°

THE HARVEST MOON

The full moon that occurs closest to the northern fall equinox is termed the Harvest Moon, since its light was said to assist farmers working late in the fields.

S K Y

SEPTEMBER

479

SOUTHERN LATITUDES THE STARS

DEEP-SKY OBJECTS

Scorpius is low in the west, with Sagittarius and the densest regions of the Milky Way above it. The large northern Summer Triangle of Altair, Vega, and Deneb is visible in the northwest, while in the southwest, Alpha (α) and Beta (β) Centauri—Rigil Kentaurus (see p.252) and Hadar—are visible from latitude 20°S and farther south. The Square of Pegasus dominates the northeastern sky. First-magnitude Fomalhaut (see p.253) in Piscis Austrinus is almost overhead, along with Capricornus and Aquarius. Achernar, the bright star at the end of the celestial river Eridanus, is high in the southeast, as is the Small Magellanic Cloud (see p.311). A group of constellations with exotic names, such as Phoenix, Tucana, Grus, and Pavo, is spread across the southern half of the sky.

Aquarius contains two famous planetary nebulae, although neither is particularly easy to find through small instruments. The Helix Nebula (see p.257), or NGC 7293, is the nearest planetary nebula to us. Its size means that its light is spread out over such a large area that clear skies are essential to glimpse it through binoculars or a low-power telescope. The Saturn Nebula, NGC 7009, is so named because, when seen through a large telescope, it appears to have rings like the planet Saturn. A small telescope shows the Saturn Nebula simply as a greenish disk. Also in Aquarius is the globular cluster M2, which resembles a fuzzy star when seen through binoculars. To the north of this is another globular cluster that can be viewed through binoculars, M15 in Pegasus.

THE SMALL MAGELLANIC CLOUD

This small satellite galaxy (left) appears beside the globular cluster 47 Tucanae (right), which is in the foreground in our own galaxy.

POSITIONS OF THE PLANETS

This chart shows the positions of the planets in September from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on September 15. Mercury is shown only when it is at greatest elongation (see p.68) – for the specific date, refer to the table, left.

NEPTUNE 19

18

17

16

15

14

13

12

11

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Neptune

EXAMPLES

13

AQUARIUS

18

Jupiter’s position on September 15, 2013

Saturn’s position on September 15, 2018. The arrow indicates the planet is in retrograde motion (see p.68).

30°

3PM 9PM

20°

6PM

Arcturus 10°

Altair

AQUARIUS OPHIUCHUS

VIRGO 12

CAPRICORNUS

13

14

18

19

17

18

19

16

15 14

18

V

Shaula

SCORPIUS

E

N

I N

G

S K Y

15

–10°

18 –20°

–30°

T HE N I G H T S K Y

LIBRA

E

14

16

0° 19

Antares

16

SAGITTARIUS

12

13

17

16

M 13

VE

M 51

M 92

Vega

AC O

GN De

DR

CY

UL

LYR A zar

NA RO LIS C O REA BO M

ne b

T H E B DIPP IG ER

M39

LA

CEPHEU

Polaris

M81

3

CO M

BO

ES

A

NORTH

CE

S

RT

M

03 M1

IA

AN

PE

ELO

X LYN

CAM

SIO

52

CAS

N

O R

BE

L O O K I N G N O RT H

UR SA M INOR

US

Mi

M1 01

I

R

MAJO R

MINO

URS A

LEO

T Ar ru s

T

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

Planetary nebula

NG

M

G

C

31

N

86

9

LIS

84

DA

C8

PAR

60°N

lla pe Ca

r sto Ca

40°N

PE

20°N

POINTS OF REFERENCE Horizons

I

G

IN

RI

M

AU

GE

M

N

38

O

37

T

M

R

H

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES Date

August 15 September 1 September 15 October 1

60°N

October 15

Zeniths

Daylightsaving time

1am

Ecliptic

Midnight

11pm

10pm

9pm

20°N

EAST

RC

C

AN ES

NA T IC

Variable star

n

HE

CE S

O TE S

I

T

RE N

S

5

DES

HYA

TH E N I G H T S KY

ctu

W

E

4

bara

Alde

US

TAU R

1

M

PU

H

3

S

CA 2

DE

T

ENS 1

PL

SERP 0

STAR MAGNITUDES -1

EIA

S

A

E

A

LUM GU

ES

ARI 36 M

TR

ED A M RO

D

3 M3

34 M

IAN

S EU

RS

A

SEPTEMBER | NO R THE R N L AT I T UDE S

WEST

480

O

T

U

E A S

T

SC

PH

ES

OE

PT OR

X

UL

NI

SC t

lhau

Fom a

PISC

S

M30

A

SOUTH

INDUS

MICROSCOPIUM

NU CAPRICOR

Alb M5

5

SAG

ECL IPTIC

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

A S

11

M

M

2

54

M2

26

M

UM

69

M

Horizons

60°N

M

18

TE

S LE

CO

U PI

40°N

20°N

M

25

28

Zeniths

A

M

21

17 M 4 23 2 M M

M AR

NA S RO ALI O C TR S AU

M

S

T CU

S

N PE A R D SE AU C

POINTS OF REFERENCE

AR ITT

LA

IU

UL PE C

UI AQ

A TT

ireo

GI SA ir

ta Al

PAVO

S

HIN

27

US

M

HE

S LE

RC U

M29

DELP EUS

LOOKING SOUTH

TUCAN

M2

L EQUU

M15

A QU A R I U S

STRINUS

SU

GRUS

IS AU

PE GA

S

O

U

7

l au

T

H

Sh

60°N

M

I

M57

SEPTEMBER | N OR TH E R N L AT I T UDE S

H

PI

L

a

M1 0

VU

16 M

CYGNUS

M

14 6 M

8 M

O

PH

W

E

12 M M1 9

US

UC H M

9

OR SC

US

T

EAST

S

tar

es 40°N

20°N

South

North

Ecliptic

STAR MOTION

S

AN ERI D

PI

S

2

TU

M6

CE

US

ira

An

M

WEST

481

M

S

M

SE

L PE C

A

IC Alt air

6 M

O

EN

UM

S

HU

CA

UD

11

U AQ

IL

N U

S

M29

LPH

R 7

DE M2

HE

RC U NUS

SA G ITT A UL A

Alb ireo

C YG

PR

10

UC 7

VU

M5

AC O

CA

RP

HI A Veg a

A

LE M

DR

LY R

M2

92

UT

OP

AP S

H

S

W

E

T

SC

12

SC UT 13

N

O R

T

4 M1

2

3

4

5

Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

EQ U

M2

M15

M39

ULE US

INU S

Deneb

LACERTA

CEPHEUS

NORTH

L O O K I N G N O RT H

Open cluster

Diffuse nebula

M52

Planetary nebula

ECL

US

ED

A

IPTI C

AS

ROM

PEG

AND

M3

EIA

1

IOP

03 M1

SS CA

0°

20°S

NG

C

86

9

40°S

E

4

33

RS

M

PE

TR

I

O

EU

N

R

T

H

Standard time

Daylightsaving time

9 pm

40°S

Ecliptic

10 pm

11 pm

Midnight

1 am

20°S

8 pm

9 pm

10 pm

11 pm

Midnight

OBSERVATION TIMES Date

August 15 September 1 September 15 October 1

0°

October 15

Zeniths

88

SC

C

PI

NG

POINTS OF REFERENCE Horizons

TH E N I G H T S KY

M

PEN 1

EAST

a

Mir

M

SER 0

STAR MAGNITUDES -1

IE

S

S

TU

CE

AR

T

G

U

LU

S

34 M

A

E

N

A S

S

S RIU AQ UA

SEPTEMBER | S O UTHE R N L AT I T UDE S

WEST

482

M

C

L AE

CO

L

UM

E

BA

H

A S

O

S

O

U

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PP

UM

PU

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s

pu

no

Ca

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UL

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DO

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RA

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VELA

P

INDUS

SOUTH

CARINA

CHAMAELEON

OCTANS

ANA

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MICROSCO

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MUS

APUS

PAVO

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RN

LOOKING SOUTH

A

VOLA NS

MENS

C

SM

TUC

GRU

PIS CIS ST RIN US

104

RUS

NGC

LMC

HYD

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Ach

NI

R

AU

CA

O PRIC 55

I

M

S

0

1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

M22

CA ux Acr

M25

8

INU

C

Horizons

0°

20°S

S

NG

40°S

C

S

S

M1 9

Zeniths

R AU T EN

U

M9

39

U

51

I RP

A

O

RM

SC

NO

S

3

M2

POINTS OF REFERENCE

X

x cru Be x cru Ga

il rus Rig ntau Ke

CRU

M24 M17

r da Ha

C CIR

M LU GU LE N A I A TR TR AU S

NA S RO ALI O C TR S AU M IU OP C ES TEL A AR

G SA

54 M

IU

TT AR

SEPTEMBER | S O UT H E R N LAT I T UDE S

EAST H

T

AX U

ID AN

PH

TO

S

S

9 M6

M8

ha

O

0°

T

H

PU

U

LU

HI OP

M 2 1 M 18 M 16

M6

ula

M2 7 M

M30

62 M

ha ut

Fo m al

tar An

U

M

es M4

S

F

N OR RO

ER

S

E

TU

T

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W

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40°S

South

North

Ecliptic

STAR MOTION

S

A 80

UC H

US

RA

U AQ

LIB

RI

483

WEST

484

MONTHLY SKY GUIDE

OCTOBER

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

October 29 October 18 October 8 October 27 October 16 October 5 October 24 October 13

October 15 October 5 October 23 October 13 October 1, 30 October 19 October 9 October 28

The Square of Pegasus takes center stage in the northern skies in both hemispheres, a sign of the arrival of the northern fall and the southern spring. Northeast of it lies the Andromeda Galaxy, the closest large galaxy to the Earth. South of the Square, a band of faint zodiacal constellations crosses the sky, from Aries in the east to Capricornus in the southwest.

NORTHERN LATITUDES

PLANETS

2012: October 4–5 Mercury and Saturn are 3.2° apart in the western evening sky.

THE STARS

2012: October 26 Mercury is at greatest evening elongation, magnitude -0.1.

The Square of Pegasus lies high in the sky from mid-northern latitudes. From one corner of the Square, the stars of Andromeda extend northeastward toward Perseus and Cassiopeia. Capella twinkles above the horizon in Auriga, lower in the northeast. In the north, the Big Dipper is at its lowest, and it is below the horizon for observers south of about latitude 30°N. Directly beneath the Square of Pegasus is a loop of stars known as the Circlet, representing the body of one of the fish in the zodiacal constellation of Pisces. Fomalhaut (see

2013: October 9 Mercury is at greatest evening elongation, magnitude 0.0. 2013: October 10 Mercury and Saturn are 5° apart in the southwestern evening sky. 2015: October 16 Mercury is at greatest morning elongation, magnitude -0.5. 2015: October 17–30 Venus, Jupiter, and Mars appear within 6° of each other in the eastern morning sky. 2016: October 30 Venus and Saturn are 3° apart in the southwestern evening sky. 2019: October 20 Mercury is at greatest evening elongation, magnitude -0.1. ECLIPSES

2014: October 8 A total eclipse of the Moon is visible from east Asia and North America.

p.253) in Piscis Austrinus is low on the southern horizon beneath the stars of Aquarius. In the western sky, the Summer Triangle lingers, while in the east, Taurus leads the stars of winter into view.

High in the north, M52, an open cluster near Cassiopeia, is visible through binoculars. Between this and the Square of Pegasus lies an often-overlooked planetary nebula, NGC 7662, nicknamed the Blue Snowball. A small telescope is needed to see it.

DEEP-SKY OBJECTS October evenings are a good time to view the Andromeda Galaxy, M31 (see pp.312–313). It can be seen as an elongated misty patch with the naked eye, if skies are not too polluted, and it is easily visible through binoculars, spanning a greater width than a full moon.

METEOR SHOWER One of the year’s lesser showers, the Orionids, reaches a peak of some 25 meteors an hour around October 21. They radiate from northern Orion, near the border with Gemini. This area rises late, so the meteors are best seen after midnight. 3AM

6AM

2014: October 23 A partial eclipse of the Sun is visible from central and western USA, Canada, and Mexico.

MIDNIGHT

9AM Capella

Castor Pollux

TAURUS

GEMINI 13

LEO

20°

13 10°

12

VIRGO 17

0°

19 14

15

15

Regulus

ARIES

Aldebaran

14

Hyades

CANCER

Betelgeuse Procyon

15

17

12

Pleiades

Bellatrix

15

Mira

16

Rigel

–10°

–20°

TH E N I G H T S KY

POSITIONS OF THE PLANETS –30°

This chart shows the positions of the planets in October from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on October 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

–40°

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Neptune

THE SQUARE OF PEGASUS

EXAMPLES

13

Jupiter’s position on October 15, 2013

12

Jupiter’s position on October 15, 2012. The arrow indicates the planet is in retrograde motion (see p.68).

This huge square in the northern fall sky is composed of three stars in Pegasus and one in Andromeda (top, left).

OCTOBER

485

SOUTHERN LATITUDES THE STARS In contrast to the sparkling skies of southern winter, the constellations of October evenings are mostly faint and unremarkable. One star

that stands out is 1st-magnitude Fomalhaut (see p.253), almost overhead in the constellation Piscis Austrinus. In the northwest sky is Altair (see p.252) in Aquila and,

DEEP-SKY OBJECTS

high in the north, the Square of Pegasus. Between Pegasus and Fomalhaut lies Aquarius, the Water Carrier. More constellations with watery associations fill the eastern part of the sky— Pisces, the Fish; Cetus, the Sea Monster or the Whale; and Eridanus, the River. The constellation Eridanus ends at the bright star Achernar, high in the south. The Small Magellanic Cloud (see p.311) is lower in the south, with the Large Magellanic Cloud (see p.311) now in view in the southeast. Canopus in Carina is also visible in the southeast, for those farther south of the equator than 20°S.

Tucana contains the second-best globular cluster in the sky, 47 Tucanae, or NGC 104, which is visible to the naked eye as a fuzzy star and appears impressive through binoculars. It covers the same area of sky as a full moon, near the Small Magellanic Cloud, but it lies much closer to us—about 15,000 light-years away—in our own Galaxy. On the edge of the SMC, NGC 362 is another, fainter globular cluster, also in our galaxy. October and November evenings are the best time for southern observers to view the Andromeda Galaxy, M31 (see pp.312–313), which lies low in the northern sky. Near it is another member of our Local Group of galaxies, M33, a smaller spiral galaxy that is less easy to see. In clear, dark skies, it can be glimpsed through binoculars or a low-power telescope as a large, rounded patch.

FAMILIAR ASTERISMS

The Circlet of Pisces (left) and the Y-shaped Water Jar of Aquarius (right) are two easily recognizable star patterns in the October evening sky.

19

18

17

19

PISCES 16

15

14

13

18

17

16

15

14

13

12

1

12

AQUARIUS MIDNIGHT

CETUS URANUS

NEPTUNE NOON

9PM

20°

3PM

6PM

Arcturus 10°

PISCES Altair

AQUARIUS 0°

OPHIUCHUS

VIRGO 12 17 15

17

18

CAPRICORNUS

19

16

18

19 14

16 Antares

13

12

18

14 16

12

13

19

E

V

E

N

I N

18

–20°

–30°

Shaula –40°

G

S K Y

SCORPIUS

T HE N I G H T S K Y

LIBRA SAGITTARIUS

–10°

13 19

13

A 92

S

M29

DR A

CO

LA CE

NU PH

RT A

CE

M52

ANDROMEDA

EU S

De

LYR

Albir eo

IO

03 M1

SS CA

M81

G

RC UL CO

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A

RO

NA

BO

9

RE

AL

N

ga Ve

IS

ne b

O R

T

S

4

5

Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

Planetary nebula

9

C

88

4

ME

R PA LO

OR

DA

LI

UM

UL NG Horizons

S

60°N

N LY

lla pe Ca

X

40°N

20°N

POINTS OF REFERENCE

MIN

CA

G

86

N

C

IA

N

PE

LEO

AJOR U R SA M

is Polar

THE BIG DIPPER

NORTH

L O O K I N G N O RT H

URS A MIN OR

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Mizar

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M1 01

M 51

CA

M3

M57

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B OO TE

CYG

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38

DES M

PLEIA

AU

M

G

36

RI

ES

Zeniths

O

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T

60°N

November 15

November 1

October 15

October 1

September 15

Date

H

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES

N

b

Alde

ix

Daylightsaving time

1am

Ecliptic

Midnight

11pm

10pm

9pm

20°N

TH E N I G H T S KY

M

T

CUL

S

H

W

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STAR MAGNITUDES -1

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OCTOBER | NOR THE R N L AT I T UD E S

WEST

486

S

T

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Fo

A QU A

PEGASUS

0

1

MAGNITUDES

2

T HE N I G H T S K Y

-1

STAR 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

5

M3

IND

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M

PR

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CA

HI

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P EL

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P CO

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0

M2

M1

Horizons

60°N

40°N

20°N

Zeniths

US

A

N OR

N

r

7 M2

POINTS OF REFERENCE

US

OCTOBER | NO R THE R N LAT I T UD E S

H

ER

CL

S U

TT A

SA GI lta i

A

S

AQ UIL 55

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20°N

South

North

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STAR MOTION

S

3

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M31

C AS S I O P E I A

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M52

NORTH

L O O K I N G N O RT H

PHEU S

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

PIS

Planetary nebula

CE

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PL

EU

T

N

O

R

T

H

ES

20°S

8 pm

9 pm

10 pm

11 pm

Midnight

Standard time

OBSERVATION TIMES Date

September 15 October 1 October 15 November 1

0°

n

Daylightsaving time

1 am

Midnight

11 pm

Ecliptic

10 pm

9 pm

40°S

ara

US November 15

Zeniths

RS

S

PE

LI

40°S

POINTS OF REFERENCE Horizons

ION

OR

U AQ

I

G

LA

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A

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TH E N I G H T S KY

M11

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STAR MAGNITUDES -1

2

OCTOBER | S O UTHE R N L AT I T UD E S

WEST

488

R

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Ad

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S

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1

2

T HE N I G H T S K Y

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STAR MAGNITUDES 3

4

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Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

A

Horizons

0°

20°S

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40°S

M

M

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7

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0°

S

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A

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POINTS OF REFERENCE

RUS

S il rus Rig ntau Ke

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LOOKING SOUTH

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NGC 104

TUCANA

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EN

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OCTOBER | S OUT H E RN LAT I T UD E S

A

M

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PU

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20°S

40°S

South

North

Ecliptic

STAR MOTION

S

EN

RP

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LE

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M4

FO

M4

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SC AU D

el

M9

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res

US

Ant a

T CE

WEST

489

490

MONTHLY SKY GUIDE

NOVEMBER

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

November 28 November 17 November 6 November 25 November 14 November 4 November 23 November 12

November 13 November 3 November 22 November 11 November 29 November 18 November 7 November 26

Cassiopeia lies overhead for northern observers, as the Milky Way runs from Cygnus in the west to Gemini in the east. The large figures of Pisces, the Fish, and Cetus, the Sea Monster or Whale, are spread across the equatorial region of the sky, while in the southern sky the Large and Small Magellanic Clouds are high up.

PLANETS

NORTHERN LATITUDES

2012: November 27 Venus and Saturn are 0.5° apart in the eastern dawn sky.

THE STARS

2013: November 1 Venus is at greatest evening elongation, magnitude -4.4.

the Double Cluster, embedded in the Milky Way between Perseus and Cassiopeia. The Andromeda Galaxy, M31 (see pp.312-313), remains high up this month.

All the main characters in the Perseus and Andromeda myth (see p.368) are on display in the November evening sky. Cetus contains a remarkable variable star, Mira (see p.285). It is easily visible to the naked eye when at maximum brightness, every 11 months or so, but the rest of the time it fades out of sight. High in the west is the Square of Pegasus, with the stars of the Summer Triangle lower in the northwest.

2013: November 18 Mercury is at greatest morning elongation, magnitude -0.5. 2013: November 26 Mercury and Saturn are 2° apart in the eastern morning sky. 2014: November 1 Mercury is at greatest morning elongation, magnitude -0.5. 2017: November 23 Mercury is at greatest evening elongation, magnitude -0.3. 2018: November 6 Mercury is at greatest evening elongation, magnitude -0.2. 2019: November 28 Mercury is at greatest morning elongation, magnitude -0.5. ECLIPSES AND TRANSITS

METEOR SHOWERS The Taurids have a broad peak in the first week of the month, when around 10 meteors an hour may be seen coming from the region south of the Pleiades cluster. Although not numerous, the meteors are long-lasting and often bright. A second meteor shower in November, the Leonids, radiates from the head of Leo,

DEEP-SKY OBJECTS

2012: November 13–14 A total eclipse of the Sun is visible from northeastern Australia and the south Pacific. A partial eclipse is visible from New Zealand, the rest of Australia, and the Pacific Ocean.

Two open star clusters, NGC 457 and NGC 663, are easy to see with binoculars in Cassiopeia. Even better are NGC 869 and 884, a pair known as

2013: November 3 A total eclipse of the Sun is visible from the mid Atlantic Ocean and Central Africa. 2019: November 3 The transit of Mercury across the Sun is visible from North America, South America, Europe, Africa, and central Asia.

THE PRINCESS, HERO, KING, AND QUEEN

Joined in Greek myth, Andromeda (right), Perseus (bottom), Cepheus (top), and Cassiopeia (center) appear together in northern skies in November.

reaching a peak around November 17. Usually, no more than 10 meteors per hour are seen, but surges of activity occur every 33 years or so. High activity is not expected again until around 2032.

3AM MIDNIGHT

6AM

Capella

9AM

Castor Pollux

GEMINI Pleiades 13

CANCER LEO

Arcturus 10°

0° 12

VIRGO

14 –10°

TH E N I G H T S KY

–20°

–30°

17

19 13

17

LIBRA

12 19

17

15

Hyades Betelgeuse Procyon

15

Bellatrix

16

Rigel

18

13

M O R N I N G

S K Y

POSITIONS OF THE PLANETS

This chart shows the positions of the planets in November from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on November 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

–40°

–50°

TAURUS

Aldebaran

14 Regulus

13 15

12

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Neptune

EXAMPLES

13

Jupiter’s position on November 15, 2013

12

Jupiter’s position on November 15, 2012. The arrow indicates the planet is in retrograde motion (see p.68).

NOVEMBER

491

SOUTHERN LATITUDES THE STARS

DEEP-SKY OBJECTS

Achernar, the bright star at the end of Eridanus, lies high in the south on November evenings. The other stars of Eridanus extend to Orion, which is rising in the east. Aldebaran and the stars of Taurus are in the northeast, and the Square of Pegasus is high in the northwest. Aquarius is in the west, with Fomalhaut (see p.253) in Piscis Austrinus in the southwest. The Large and Small Magellanic Clouds (see p.310 and p.311) are high in the south. Brilliant Canopus in Carina is in the southeast, with Sirius (see p.268) in Canis Major rising in the east. Overhead is Cetus, containing the long-period variable star Mira.

South of the head of Cetus is M77, the brightest of the Seyferttype galaxies (see p.320). Seyferts are spiral galaxies with unusually bright centers, caused by hot gas spiraling around a massive black hole. A telescope is required to see M77. In the south, the globular cluster 47 Tucanae is still in view near the meridian. The Large Magellanic Cloud, with the Tarantula Nebula, NGC 2070, is in the southeast, but it is best seen in January. In the north, the galaxies M31 and M33 are visible, while the Pleiades (see p.291) and Hyades clusters (see p.290) are moving higher in the east.

URANUS

NEPTUNE

19

18

17

19

PISCES 16

15

14

13

18

17

16

15

14

13

12

11

12

AQUARIUS

CETUS

CLASSIC VARIABLE

The long-period variable star Mira (center) appears strongly red when near maximum brightness. The 9th-magnitude star to its left is unrelated.

9PM

6PM

NOON

ARIES 3PM

PISCES

10°

Altair

AQUARIUS

0°

Mira

OPHIUCHUS –10°

CAPRICORNUS 18

14 16

V

E

N

I N

17 14

18 16 13

12

15 19

19

17

18

Antares

Fomalhaut

SAGITTARIUS

G

S

K

14

–20°

18 –30°

Shaula –40°

Y

SCORPIUS –50°

T HE N I G H T S K Y

E

19

16

AQU

ir

SAG ILA

HIN US M2

ITTA Al

29

13

M

US 92

De ne b

M 39

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M

bi

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M

LA

7

57

re

HE

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RC DRA

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T

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UL

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H

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M

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A

N

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3

4

5

Variable star

CO

AN

S

M3

DA

C

1

AS S

URSA

M52

ME

HEU

DR O

CEP

BOO TES

Globular cluster

DEEP-SKY OBJECTS Galaxy

M103

NG

C

86

9

NG

Polaris

Mizar

M51

NORTH

M101

MINOR

IOPE IA

Open cluster

Diffuse nebula

C

4

PE 88

RS

ME

R PA LO

M81

BIG THE ER DIPP

DA

TICI VENA

CA

CANES

Planetary nebula

L

URS

pe

lla

OR AJ

N LY

8 M3 6

X

M3

M37

Horizons

60°N

40°N

20°N

POINTS OF REFERENCE

AM

Ca

O

sto Zeniths

M

I

N

O

R

T

60°N

December 15

December 1

November 15

November 1

October 15

Date

H

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES

LE

M35

4 M3

L O O K I N G N O RT H

IS

DELP

VU 1

Daylightsaving time

1am

Ecliptic

Midnight

11pm

10pm

9pm

20°N

EAST

TH E N I G H T S KY

Alta 0

STAR MAGNITUDES -1

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NOVEMBER | NOR THE R N L AT I T UD ES

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1

2

T HE N I G H T S K Y

-1

STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

X

ANA

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TUC

PHO

PTOR

SU GA E P

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SC UL

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GR

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Horizons

60°N

40°N

I AR

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20°N

S

M 15

Zeniths

S CI US PIS RI N ST AU

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AQ

POINTS OF REFERENCE

S

U

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M

H

60°N

O

M2

S

I

30

US

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TR

ANDR

NOVEMBER | NO R T HE R N L AT I T UDE S

EAST

AJ

M

M5

M NIS

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20°N

South

North

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STAR MOTION

S

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IU S

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ROM EDA

CEP H

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M52

M31

IOPEIA

CETUS

M33

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Mira

NGC

ARIE

M34

884

TRIANGULUM

M103

NORTH

L O O K I N G N O RT H

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Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

S

PER

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40°S

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POINTS OF REFERENCE

L DA

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Planetary nebula

M

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A

M3

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X

M

1

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O

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December 15

December 1

November 15

November 1

October 15

Date

M

35

H

20°S

8 pm

9 pm

10 pm

11 pm

Midnight

Standard time

OBSERVATION TIMES

N LY

M42

Zeniths

OS

Daylightsaving time

1 am

Midnight

11 pm

Ecliptic

10 pm

9 pm

40°S

CER

NO

TH E N I G H T S KY

Alt

H

3

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STAR MAGNITUDES -1

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NOVEMBER | S O UTHE R N L AT I T UD ES

WEST

494

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2

T HE N I G H T S K Y

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STAR MAGNITUDES 3

4

5

Variable star

Galaxy

Globular cluster

DEEP-SKY OBJECTS Open cluster

Diffuse nebula

Planetary nebula

alh

R NO

M

A

A

AR

T

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Horizons

0°

20°S

40°S

POINTS OF REFERENCE

O PAV

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Zeniths

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SOUTH

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Becrux

Acrux

NGC

SMC

Achernar

AELEON

MUSCA

CHAM

M E N SA

CRUX

LMC

UM

HYD

LOG I

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TIC

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AN

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NOVEMBER | S OUT HE R N L AT I T UDE S

A

Ad

E

M

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LA

PP

LU

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PU

CO

CA

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TA IT O ST R O N R AL A IS ul a

EAST

7

6

M

M4

93

S

2

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40°S

South

North

Ecliptic

STAR MOTION

S

M

XI

E

47

PY

O

W

M

S

OS RI U

0 54

ER OC 69

N

RN

MO

RIC O

M5

S NI C A JO R MA

M

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T

Sir 41

M

M

M2

LEP

WEST

495

496

MONTHLY SKY GUIDE

DECEMBER

SPECIAL EVENTS PHASES OF THE MOON

2012 2013 2014 2015 2016 2017 2018 2019

FULL MOON

NEW MOON

December 28 December 17 December 6 December 25 December 14 December 3 December 22 December 12

December 13 December 3 December 22 December 11 December 29 December 18 December 7 December 26

The Sun reaches its farthest point south of the celestial equator this month, on December 21–22. As a result, Northern Hemisphere nights are the longest of the year, while in the Southern Hemisphere they are the shortest. Earth has now completed another annual circuit of the Sun, and the evening stars end the year as they began, with the tableau of Orion and Taurus returning to center stage.

NORTHERN LATITUDES

PLANETS

2012: December 3 Jupiter is at opposition, magnitude -2.8. 2012: December 4 Mercury is at greatest morning elongation, magnitude -0.3. 2014: December 30 Mercury and Venus are 3.8° apart in the southwestern evening sky. 2015: December 29 Mercury is at greatest evening elongation, magnitude -0.5. 2016: December 11 Mercury is at greatest evening elongation, magnitude -0.4. 2018: December 15 Mercury is at greatest morning elongation, magnitude -1.4. ECLIPSES

2019: December 26 An annular eclipse of the Sun is visible from Saudi Arabia, India, Sumatra, and Borneo. A partial solar eclipse is visible from Asia and Australia.

THE STARS

DEEP-SKY OBJECTS

Overhead lies Perseus, containing the famous variable star Algol (see p.276). From Perseus, the Milky Way leads northwestward to Cassiopeia and Cygnus, which is out of sight for those at around 20°N or closer to the equator. In the other direction, the Milky Way extends southeastward via Auriga and past Taurus to Gemini and the northern arm of Orion. The Square of Pegasus is in the west, while the Winter Triangle of Betelgeuse (see p.256) in Orion, Procyon (see p.284) in Canis Minor, and Sirius (see p.268) in Canis Major dominates the southeast. By comparison with the richness of this southeastern part of the sky, the southwest seems dull and empty, since it is occupied by the faint constellations Aries, Pisces, and Cetus. As the year ends, Sirius lies due south around midnight.

Large, bright clusters of stars abound in the December evening sky. In central Perseus, a few dozen stars cluster around the constellation’s brightest member, Alpha (α) Persei or Mirphak. They form a group known as the Alpha Persei cluster, which covers several diameters of a full moon and is a fine sight through binoculars. In Taurus lies probably the finest open cluster in the entire sky, the Pleiades or M45 (see p.291). At least six members are visible to normal eyesight, but binoculars bring dozens more into view. Taurus contains an even larger cluster, the Hyades (see p.290), a V-shaped grouping which

outlines the Bull’s face. In addition to these groupings, the Double Cluster in Perseus, NGC 869 and NGC 884, already encountered in November, remains well placed.

METEOR SHOWER The year’s second-best meteor shower, the Geminids, reaches a peak around December 13–14, when up to one meteor per minute can be seen radiating from a point near Castor in Gemini. Lesser activity is seen for a few days before the peak, but numbers fall off rapidly afterward. MIDNIGHT 3AM

6AM

Castor

9AM

GEMINI

Pollux 13

NOON

LEO

Arcturus

Regulus

14

10°

CANCER

Betelgeuse

15

VIRGO

OPHIUCHUS

16 17

TH E N I G H T S KY

18

–30°

–50°

12

18 14 15 Antares

–40°

15 16

12

–10°

–20°

Be Procyon

13

0°

15

13 19

18 17

Spica

17

12

S

LIBRA

SCORPIUS

M

O

R

N

I N

K

Y

G

THE GEMINIDS

The Geminid meteors streak across the sky in midDecember. In this picture, the bright star at center left is Sirius and the southern part of Orion is at top right.

DECEMBER

497

SOUTHERN LATITUDES THE STARS

Canis Minor, and Sirius in Canis Major form a large triangle, which is a sign of the approaching southern summer.

The distinctive figures of Orion and Taurus are high in the northeast, with Gemini and Auriga closer to the horizon. Perseus lies low in the north, while the Square of Pegasus sets in the northwest, followed by Pisces. Fomalhaut (see p.253) in Piscis Austrinus is in the southwest. Eridanus, the River, meanders southwestward from the foot of Orion, ending at the bright star Achernar. Brighter Canopus is high in the southeast in Carina. The Large and Small Magellanic Clouds (see p.310 and p.311) lie high in the south, on either side of the celestial meridian. In the east, Betelgeuse in Orion, Procyon in

DEEP-SKY OBJECTS December and January evenings are the best time for southern observers to see the Pleiades (see p.291) and Hyades (see p.290), two large and prominent open star clusters north of the equator in Taurus. The Large Magellanic Cloud, containing the Tarantula Nebula, NGC 2070, is high in the southeast but it is better seen in January. Overall, the southern evening sky is bereft of prominent deep-sky objects near the celestial meridian this month. THE LARGE MAGELLANIC CLOUD

The LMC (bottom) lies deep in the southern sky between the bright stars Canopus (left) and Achernar (top right). The small pink patch on the LMC is the Tarantula Nebula.

POSITIONS OF THE PLANETS

This chart shows the positions of the planets in December from 2012 to 2019. The planets are represented by colored dots, while the number inside each dot denotes the year. For all planets apart from Mercury, the dot indicates the planet’s position on December 15. Mercury is shown only when it is at greatest elongation (see p.68)—for the specific date, refer to the table, left.

Mercury

Mars

Saturn

Venus

Jupiter

Uranus

Neptune

URANUS 19

18

17

EXAMPLES

14

Jupiter’s position on December 15, 2014

Jupiter’s position on December 15, 2012. The arrow indicates the planet is in retrograde motion (see p.68).

12

NEPTUNE

PISCES 16

15

19 14

13

18

17

16

12

15

14

13

12

1

AQUARIUS Capella

CETUS

6PM

TAURUS 12

Pleiades

3PM

ARIES

NOON Aldebaran

Hyades

PISCES

10°

Altair

ellatrix

AQUARIUS

0°

18

Mira Rigel

–10°

CAPRICORNUS 16 14

13 16

E

19

E

N

I N

19

–20° 18 16

14

19

17 –30°

Fomalhaut

SAGITTARIUS

G S

K

Shaula –40°

Y –50°

T HE N I G H T S K Y

V

12

15

G

N U

S

LY R

A

M52

CA

SS IO

N 9

EU 86

M3

C

M

U

NG 84

pe

ED BOOTE

ELOPARDALIS

Polaris

S

SAG

31

A ITT

CY M

M2

D R AC O

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CAM

C8

4

PEI A

M1 03

G

RS

OM 39

CE RT A M

EUS

VU

US Al bi

LP

EC U

N

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LA

O

R

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29

LES

M92

CEP H

CU

PE

DR

INU

A Ve ga

De ne b

LA

AN

15 M 57

7

T

S

5

Variable star

Globular cluster

DEEP-SKY OBJECTS Galaxy

Open cluster

Diffuse nebula

S

Planetary nebula

M81

1 M10

1

BIG THE PER DIP

zar Mi

M5

LY

UR

SV

60°N

40°N

20°N

CI

M

A

BE

Zeniths

RE

LE

N

N

O

R

T

60°N

January 15

January 1

December 15

December 1

November 15

Date

H

40°N

8pm

9pm

10pm

11pm

Midnight

Standard time

OBSERVATION TIMES

CO

I AT

R JO

EN

MA

NE

SA

CA

Pollux

POINTS OF REFERENCE Horizons

ER NC

CA

AS

PH

T

4

M67

Daylightsaving time

1am

Ecliptic

Midnight

11pm

10pm

9pm

20°N

TH E N I G H T S KY

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PEG

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EAST

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STAR MAGNITUDES -1

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DECEMBER | S O UTH E R N L AT I T UDE S

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502

GLOSSARY

GLOSSARY

G L OS S A RY

A absolute magnitude see magnitude. absorption line see spectral line. absorption nebula see nebula. accelerating universe A universe that expands at an accelerating rate. Current evidence indicates that the expansion of our universe had been slowing down under the action of gravity until about 6 billion years ago, but that since then it has been accelerating. The acceleration is believed to be driven by the repulsive influence of dark energy. See also dark energy. accretion (1) The colliding and sticking together of small, solid particles and bodies to make progressively larger ones. (2) The process by which a body grows in mass by accumulating matter from its surroundings. An accretion disk is a disk of gas that revolves around a star or a compact object such as a white dwarf, neutron star, or black hole and has been drawn in from a companion star or from neighboring gas clouds. active galaxy A galaxy that emits an exceptional amount of energy over a wide range of wavelengths, from radio waves to X-rays. An active galactic nucleus (AGN) is the compact, highly luminous core of an active galaxy that, in many cases, varies markedly in brightness over time, and is thought to be powered by the accretion of gas onto a supermassive black hole. See also black hole, galaxy. active prominence see prominence. albedo The ratio of the amount of light reflected by a body, such as a planet or a part of a planet’s surface, to the amount of light that it receives from the Sun. Albedo values range from 0, for a perfectly dark object that reflects nothing, to 1, for a perfect reflector. altazimuth mounting A mounting that enables a telescope to be rotated in altitude (around a horizontal axis) and in azimuth (around a vertical axis). Many large modern telescopes are mounted in this way, using computer-controlled motors to drive the telescope in altitude and azimuth so as to track the motion of an object across the sky. See also altitude, azimuth, equatorial mounting. altitude The angular distance between the horizon and a celestial body. Altitude takes values from 0° (for an object on the horizon) to 90° (for an object that is directly overhead). See also azimuth. annual parallax see parallax.

annual proper motion see proper motion. annular eclipse see eclipse. antimatter Material composed of antiparticles. See antiparticle. antiparticle An elementary particle that has the same mass as a particle of ordinary matter but exactly opposite values of other quantities such as spin and electrical charge. For example, the antiparticle of the negatively charged electron is the positively charged positron. If a particle and its antiparticle collide, both are annihilated and converted into energy. aperture The clear diameter of the objective lens or primary mirror of a telescope or other optical instrument. aphelion The point on its elliptical orbit at which a body such as a planet, asteroid, or comet is at its greatest distance from the Sun. apogee The point on its elliptical orbit around Earth at which a body such as the Moon or a spacecraft is at its greatest distance from Earth. See also perigee. apparent magnitude see magnitude. arachnoid A type of structure, found on the surface of Venus, that consists of concentric circular or oval fractures or ridges, together with a complex network of fractures or ridges that radiate outward. Its name derives from its superficial resemblance to a spiderweb. Typical diameters range from 30–110 miles (50 to 175 km). asterism A conspicuous pattern of stars that is not itself a constellation. A well-known example is the Big Dipper, which forms part of the constellation Ursa Major (the Great Bear). See also constellation. asteroid One of the vast number of small bodies that revolve independently around the Sun. Their diameters range from a few yards (meters) to around 600 miles (1,000 km). While the greatest concentration of asteroids is in the Main Belt, which lies between the orbits of Mars and Jupiter, asteroids are found throughout the solar system. A near-Earth asteroid (NEA) is a body whose orbit comes close to, or intersects, the orbit of Earth. Formally, a near-Earth asteroid is defined as one that has a perihelion distance of less than 1.3 times Earth’s mean distance from the Sun. See also Kuiper Belt. astronomical unit (AU) A unit of distance measurement equal to the semimajor axis of Earth’s elliptical orbit, equivalent to the average of the maximum and minimum distances between Earth and Sun. 1 AU = 92,956,000 miles (149,598,000 km).

atom A basic building block of matter that is the smallest unit of a chemical element possessing the characteristics of that element. It consists of a nucleus of protons and neutrons, surrounded by a cloud of electrons. An atom has the same number of orbiting electrons as it has protons, so it is neutral (has no electrical charge). The chemical identity of an atom is determined by the number of protons in its nucleus (its atomic number). An atom of hydrogen (the simplest and lightest element) consists of a single proton and a single electron. See also electron, neutron, proton. aurora A glowing, fluctuating display of light that is produced when charged particles entering a planet’s upper atmosphere, usually in the vicinity of its north and south magnetic poles, collide with atoms and stimulate them to emit light. autumnal equinox see equinox. azimuth The angle between the north point on an observer’s horizon and a celestial object, measured in a clockwise direction around the horizon. The azimuth of due north is 0°, due east 90°, due south 180°, and due west 270°. See also altitude.

B background radiation see cosmic microwave background radiation. barred spiral galaxy A galaxy that has spiral arms emanating from the ends of an elongated, bar-shaped, nucleus. See also galaxy, spiral galaxy. baryon A particle, composed of three quarks, that is acted on by the strong nuclear force. Examples include protons and neutrons, the building blocks of atomic nuclei. Big Bang The event in which the universe was born. According to Big Bang theory, the universe originated a finite time ago in an extremely hot, dense initial state and ever since then has been expanding. The Big Bang was the origin of space, time, and matter. Big Crunch The final state that will be reached by the universe if it eventually ceases to expand and then collapses in on itself. Big Rip The tearing apart of all forms of structure in the universe—galaxy clusters, galaxies, stars, planets, atoms, and elementary particles—that is expected to occur should the repulsive effect of dark energy become infinitely strong in a finite time. See also dark energy. binary star Two stars that revolve around each other under the influence of their mutual gravitational attraction.

Each member star orbits the center of mass of the system, a point that lies closer to the more massive of the two stars. A spectroscopic binary is a system in which the two stars are too close to be resolved into separate points of light, but whose binary nature is revealed by its spectrum. The combined spectrum of the two stars contains two sets of spectral lines that shift in wavelength as the stars revolve around each other. An eclipsing binary is a system in which each star alternately passes in front of the other, cutting off all or part of its light and causing a periodic variation in the combined light of the two stars. See also Doppler effect, spectral line. black body An idealized body that absorbs and reemits all the radiation that falls on its surface and which is a perfect radiator. A black body emits a continuous spectrum of radiation (black-body radiation) that peaks in brightness at a wavelength that depends on its surface temperature— the higher the temperature, the shorter the wavelength of peak brightness. See also spectrum. black dwarf star A white dwarf star that has cooled to such a low temperature that it emits no detectable light. There has not been enough time since the origin of the universe for any star to cool down enough to become a black dwarf. See also brown dwarf star, white dwarf star. black hole A compact region of space, surrounding a collapsed mass, within which gravity is so powerful that no material object, light, or any other kind of radiation can escape to the outside universe. The radius of a black hole is called the Schwarzschild radius, and its boundary is known as the event horizon. The greater its mass, the larger its radius. When a body collapses to form a black hole, all of its mass becomes compressed into a central point, a point of infinite density called a singularity. A stellarmass black hole forms when the core of a high-mass star collapses; its mass is likely to be in the region of 3–100 times the mass of the Sun. A supermassive black hole, with a mass in the region of a few million to a few billion solar masses, is an object that forms when a very large mass collapses, or a number of black holes merge into one, in the core of a galaxy. See also active galaxy, singularity. blazar The most variable type of active galaxy, which includes BL Lacertae objects and the most violently variable quasars. See also active galaxy, BL Lacertae object, quasar.

GLOSSARY BL Lacertae object A type of active galaxy that has no detectable absorption or emission lines in its spectrum but which is believed to be similar to a quasar. The name derives from an object in the constellation Lacerta that was at first thought to be a variable star. See also quasar. blue shift The displacement of spectral lines to shorter wavelengths that occurs when a light source is approaching an observer. See also Doppler effect, red shift, spectral line. Bok globule A compact dark nebula, roughly spherical in shape, which contains 1 to 1000 solar masses of gas and dust and has a diameter of between 0.1 and a few light-years. Globules of this kind are believed to be cool concentrations of gas and dust that eventually will collapse to form protostars. They are named after Dutch-born astronomer Bart Bok, who made a detailed study of these objects. See also protostar. brown dwarf star A body that forms out of a contracting cloud of gas in the same way as a star, but, because it contains too little mass, never becomes hot enough to ignite the nuclear-fusion reactions that power a normal star. With less than 8 percent of the Sun’s mass, a brown dwarf glows dimly at infrared wavelengths, fading gradually as it cools down.

C

closed universe A universe that is curved in such a way that space is finite but has no discernible boundary (analogous to the surface of a sphere). A universe will be closed if its average density exceeds a particular value called the critical density. In the absence of a repulsive force, a closed universe will eventually cease to expand and will then collapse. See also flat universe, open universe, oscillating universe. coma The cloud of gas and dust that surrounds the nucleus of a comet and which comprises its glowing “head.” See also comet. comet A small body composed mainly of dust-laden ice that revolves around the Sun, usually in a highly elongated orbit. Each time it approaches the Sun, gas and dust evaporate from its nucleus (the solid core of the comet) to form an extensive cloud, called the coma, and one or more tails. See also coma, tail. conjunction A close alignment in the sky of two celestial bodies, which occurs when both bodies lie in the same direction as viewed from Earth. When a planet lies directly on the opposite side of the Sun from Earth, it is said to be at superior conjunction. If a planet passes between Earth and the Sun (Mercury and Venus are the only planets that can do this), it is said to be at inferior conjunction. See also opposition. constellation One of 88 regions of the celestial sphere. Each constellation contains a grouping of stars joined by imaginary lines to represent a figure. The constellations are officially referred to by the Latin names of these figures. Many have been named after mythological characters or creatures (such as Orion, the Hunter) but some after more mundane objects (for example, Sextans, the Sextant). See also asterism. continuous spectrum see spectrum. convection The transport of heat by rising bubbles or plumes of hot liquid or gas. In a convection cell, rising streams of hot material cool, spread out, and then sink down to be reheated, so maintaining a continuous circulation. core (1) The dense central region of a planet. (2) The central region of a star within which energy is generated by means of nuclear-fusion reactions. (3) A dense concentration of material within a gas cloud. Coriolis effect The tendency of a wind or current to be deflected from its initial direction as a consequence of a planet’s rotation. In the case of Earth, the deflection is to the right in the Northern Hemisphere and to the left in the Southern Hemisphere. corona The outermost region of the atmosphere of the Sun or a star. The solar corona has an extremely low density and a very high temperature (about 2–9 million degrees Fahrenheit/

1–5 million degrees Celsius). It cannot be observed except during a total eclipse of the Sun. See also eclipse, solar wind. coronal mass ejection A huge, rapidly expanding bubble of plasma that is ejected from the Sun’s corona. Containing billions of tons of material in the form of ions and electrons, together with associated magnetic fields, a typical coronal mass ejection propagates outward through interplanetary space at a speed of several hundred miles (kilometers) per second. See also corona, ion, plasma. cosmic microwave background radiation (CMBR) Remnant radiation from the Big Bang, which is detectable as a faint distribution of microwave radiation across the whole sky. See also Big Bang. cosmic rays Highly energetic subatomic particles, such as electrons, protons, and atomic nuclei, that hurtle through space at speeds close to the speed of light. cosmological constant An extra term in Einstein’s relativity equations which, if it has a positive value, corresponds to a repulsive force that could cause the universe to expand at an accelerating rate. Modern cosmologists associate the constant with a quantity called vacuum energy (residual energy that, according to quantum theory, exists even in a vacuum), one of the possible forms of the dark energy believed to permeate the universe. See also dark energy. cosmological red shift see red shift. cosmology The study of the nature, structure, origin, and evolution of the universe. crater A bowl- or saucer-shaped depression in the surface of a planet or satellite, or at the summit of a volcano. Many have raised walls and some have a central peak. An impact crater is one excavated by an meteorite, asteroid, or comet impact, whereas a volcanic crater is the cavity from which a volcano discharges material. Raised walls are created by accumulation of ejected material. critical density see flat universe. crust The thin, rocky, outermost layer of a planet or major planetary satellite, which, like Earth, has separated into several layers, with the densest material toward its center and the least dense at its surface.

D dark energy A little-understood form of energy that appears to comprise about 70 percent of the total amount of mass and energy in the universe. It exerts a repulsive effect and is believed to be causing the expansion of the universe to accelerate. See also accelerating universe.

G L OS S A RY

caldera A bowl-shaped depression caused by the collapse of a volcanic structure into an emptied magma chamber. A caldera is usually found at the summit of shield volcanoes such as those found on Venus, Earth, and Mars. captured rotation See synchronous rotation. carbonaceous chondrite see chondrite. cataclysmic variable see variable star. catadioptric telescope A type of telescope that combines mirror and lens components, rather than one or the other, to bring light to a focus. Schmidt–Cassegrain telescopes are a popular type of catadioptric telescope. See also reflecting telescope, Schmidt– Cassegrain telescope. celestial equator A great circle on the celestial sphere that is a projection of Earth’s own equator onto the celestial sphere. See also celestial sphere, great circle. celestial poles The two points at which the line of Earth’s axis, extended outward, meets the celestial sphere and around which the stars appear to revolve. The north celestial pole lies directly above Earth’s North Pole and the south celestial pole directly above Earth’s South Pole. See also celestial sphere. celestial sphere An imaginary sphere, that surrounds Earth. As Earth rotates from west to east, the sphere appears

to rotate from east to west. In order to define the positions of stars and other celestial bodies, it is convenient to think of them as being attached to the inside surface of this sphere. See also celestial equator, celestial poles. center of mass The point within an isolated system of bodies around which those bodies revolve. Where the system consists of two bodies (for example, a binary star), it is located at a point on a line joining their centers. If both bodies have the same mass, the center of mass lies midway between them, whereas if one body is more massive than the other, it lies closer to the more massive of the two. Cepheid variable A type of variable star that increases and decreases in brightness in a regular, periodic way. Cepheids are pulsating variables, which vary in brightness as they expand and contract. The more luminous the Cepheid, the longer its period of variation. See also variable star. Chandrasekhar limit The maximum possible mass for a white dwarf star. If the mass of a white dwarf exceeds this limit, which is about 1.4 solar masses, gravity will overwhelm its internal pressure and it will collapse. The limit was first calculated by Indian astrophysicist Subrahmanyan Chandrasekhar in 1931. See also white dwarf star. charge-coupled device (CCD) An electronic imaging device that consists of a large array of tiny lightsensitive elements. The image of an object is constructed by reading off the electrical charges that accumulate in each element during an exposure. chondrite A stony meteorite that contains a large number of small, spherical objects called chondrules. A carbonaceous chondrite is one that is rich in carbon, carbon compounds, and volatile materials. Carbonaceous chondrites are thought to be some of the least-altered primitive remnants of the protoplanetary disk from which the solar system formed. See also meteorite, protoplanetary disk. chromosphere The thin layer in the Sun’s atmosphere that lies between the photosphere (the visible surface) and the corona. Its faint, reddishpink light can be seen directly during a total eclipse of the Sun when the Moon hides the dazzling photosphere. See also photosphere. circumpolar A term used to describe a star, or other celestial body, that remains above the horizon at all times when viewed from a particular place on Earth’s surface. circumstellar disk A flattened, diskshaped cloud of gas and dust that surrounds a star. A disk of this kind is usually associated with a young or newly forming star, in which case it is composed of material from the original dusty gas cloud that collapsed to form the central star. See also protoplanetary disk.

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GLOSSARY dark matter Matter that exerts a gravitational influence on its surroundings but does not emit detectable amounts of radiation. Dark matter appears to make up a large fraction of the total amount of mass contained in galaxies, galaxy clusters, and the universe as a whole. dark nebula see nebula. declination The angular distance of a celestial body north or south of the celestial equator. Declination is positive (+) if the object is north of the celestial equator and negative (-) if it is south of the celestial equator. A star on the celestial equator has a declination of 0°, whereas a star at one of the celestial poles has a declination of 90°. See also celestial equator, celestial sphere, right ascension. declination axis see equatorial mounting. diffuse nebula A luminous cloud of gas and dust. The term “diffuse” refers to the cloud’s fuzzy appearance and to the fact that it cannot be resolved into individual stars. See also nebula. direct motion see retrograde motion. direct rotation see retrograde rotation. Doppler effect The observed change in the wavelength or frequency of radiation that is caused by the motion of its source toward or away from an observer. See also blue shift, red shift. double star Two stars that appear close together in the sky. If the two stars revolve around each other, the system is called a binary. An optical double star consists of two stars that appear to be close together only because they happen to lie in almost exactly the same direction when viewed from Earth; they lie at different distances and are not physically connected. See also binary star. dwarf planet A celestial body that orbits the Sun and has sufficient mass and gravity to be spherical, but has not cleared the region around its orbit of other bodies, and is not a satellite. dwarf star An alternative name for a main-sequence star that was originally devised to distinguish main-sequence stars, such as the Sun, from the much more luminous giant stars on the Hertzsprung–Russell diagram. See also Hertzsprung–Russell diagram, main sequence.

G L OS S A RY

E eccentricity (e) A measure of how much an ellipse deviates from a perfect circle. Eccentricity takes a value between 0 and 1; a circle has eccentricity of 0, and the most elongated ellipses approach an eccentricity of 1. See also ellipse. eclipse The passage of one celestial body into the shadow cast by another. A lunar eclipse occurs when the Moon passes into Earth’s shadow and a solar eclipse when part of Earth’s surface enters the shadow cast by the Moon. A total lunar eclipse

takes place when the whole of the Moon lies within the dark cone of Earth’s shadow, and a partial lunar eclipse when only part of the Moon is in the shadow. During a total solar eclipse, the Sun is completely obscured by the dark disk of the Moon. A partial solar eclipse occurs when only part of the Sun’s surface is hidden. If the Moon passes directly between the Sun and Earth when it is close to apogee, it will appear smaller than the Sun, and its dark disk will be surrounded by a ring, or annulus, of sunlight; an event of this kind is called an annular eclipse. See also apogee. eclipsing binary see binary star. ecliptic The track along which the Sun appears to travel around the celestial sphere, relative to the background stars, in the course of a year. It is equivalent to the plane of Earth’s orbit. ejecta Material thrown outward by the blast of an impact. Ejecta, which is produced when a meteorite strikes the surface of a planet or moon and excavates a crater, consists of freshly exposed material that may be markedly brighter than the adjacent surface. Sometimes the ejected material forms extensive streaks, or rays, which radiate from the point of impact. An ejecta blanket is a continuous sheet of deposited ejecta that surrounds a crater. See also crater. electromagnetic (EM) radiation Oscillating electric and magnetic disturbances that propagate energy through space in the form of waves (electromagnetic waves). Examples include light and radio waves. electromagnetic spectrum The complete range of electromagnetic radiation from the shortest wavelengths (gamma rays) to the longest wavelengths (radio waves). electron A lightweight fundamental particle with negative electrical charge. A cloud of electrons surrounds the nucleus of an atom. The number of orbiting electrons in an atom is the same as the number of protons in its nucleus. ellipse An oval curve drawn around two points called foci (singular: focus) such that the total distance from one focus to any point on the curve and then back to the other focus is constant. The maximum diameter of an ellipse is the major axis, and half of this diameter is the semimajor axis. The two foci lie on the major axis; the greater their separation, the more elongated the ellipse. See also eccentricity, orbit. elliptical galaxy A galaxy that appears round or elliptical in shape and normally contains very little gas or dust. See also galaxy. elongation The angle between the Sun and a planet, or other solar system body, when viewed from Earth. The elongation of a planet is 0° when it is in conjunction with the Sun and 180° when it is at opposition. Greatest

elongation is the maximum possible elongation of a body, such as Mercury or Venus, that lies inside the orbit of Earth. See also conjunction, opposition. emission line see spectral line. emission nebula see nebula. equatorial mounting A mounting that allows a telescope to be turned around two axes, one of which (the polar axis) is parallel to, and the other (the declination axis) perpendicular to, Earth’s axis of rotation. The telescope can follow the motion of a celestial object across the sky by being driven around the polar axis in the opposite direction of Earth’s rotation at a rate of one revolution per sidereal day. See also declination, right ascension, sidereal time. equinox An occasion when the Sun is vertically overhead at a planet’s equator, and day and night have equal duration for the whole planet. In the case of Earth, the northern vernal equinox is the point at which the Sun crosses the celestial equator from south to north, on or around March 20 each year, and the northern autumnal equinox is the point at which the Sun crosses the celestial equator from north to south, on or around September 22. See also right ascension. eruptive prominence see prominence. eruptive variable see variable star. escape velocity The minimum speed at which a projectile must be launched in order to recede forever from a massive body and not fall back. The escape velocity at Earth’s surface is 25,200 mph (40,320 km/h). event horizon see black hole. extrasolar planet (exoplanet) A planet that revolves around a star other than the Sun.

F facula (plural: faculae) A patch of enhanced brightness on the solar photosphere that may be seen in a white-light image of the Sun, usually near the edge of the Sun’s visible disk where the background brightness is lower. Faculae correspond to regions that are hotter than their immediate surroundings. They are associated with active solar regions but may appear before, and persist after, any sunspots that develop in those regions. See also photosphere, sunspot. Fraunhofer line One of the 574 dark absorption lines in the spectrum of the Sun that were identified by the 19th-century German optician and instrument-maker Joseph von Fraunhofer. See also spectral line. flare star A faint, cool, red dwarf star that displays sudden, short-lived increases in luminosity caused by extremely powerful flares that occur above its surface. See also red dwarf star. flat universe A universe in which the overall net curvature of space is zero.

In such a universe, space is flat in the sense that, apart from localized distortions caused by massive bodies, its large-scale geometry is Euclidean and light rays travel in straight lines. A universe will be flat if its overall average density is equal to a particular value, called the critical density. See also closed universe, open universe, oscillating universe. focal length The distance between the center of a lens, or the front surface of a concave mirror, and the point at which it forms a sharp image of a very distant object. frequency The number of wave crests of a wave motion that pass a given point in one second. In the case of an electromagnetic wave (for example, light) the frequency is equal to the speed of light divided by the wavelength. See also electromagnetic radiation. fusion (nuclear fusion) The process by which atomic nuclei are joined together during energetic collisions to form heavier atomic nuclei, with an associated release of large amounts of energy. Stars are powered by fusion reactions that take place in their central cores. In a main-sequence star such as the Sun, fusion reactions convert hydrogen into helium. See also main sequence.

G galactic cluster see open cluster. galaxy A large aggregation of stars and clouds of gas and dust. Galaxies, which may be elliptical, spiral, or irregular in shape, contain from a few million to several trillion stars and have diameters ranging from a few thousand to over a hundred thousand light-years. The Sun is a member of the Milky Way galaxy, which is also sometimes known as the Galaxy. See also Milky Way. galaxy cluster An aggregation of galaxies held together by gravity. Clusters that contain up to a few tens of member galaxies are called groups. Larger clusters are divided into regular and irregular clusters, depending on their degree of structure. The most richly populated regular clusters (rich clusters) contain up to several thousand galaxies. galaxy supercluster A cluster of galaxy clusters, which is a loose aggregation of up to about ten thousand galaxies, spread through a volume of space with a diameter of up to about 200 million light-years. See also galaxy cluster. Galilean moon One of the four largest natural satellites of the planet Jupiter, which were discovered in 1610 by the Italian astronomer Galileo Galilei. In order of distance from the planet, they are Io, Europa, Ganymede, and Callisto.

GLOSSARY gravity The attractive force that acts between material bodies, particles, and photons. According to the theory of gravity developed in the 17th century by Isaac Newton (Newtonian gravitation), the force of gravity acting between two bodies is proportional to the product of their masses divided by the square of the distance between their centers. For example, if the distance between the bodies is doubled, the force of attraction is reduced to one quarter of its previous value. See also relativity. great circle A circle on the surface of a sphere, the plane of which passes through the center of the sphere and which exactly divides the sphere into two equal hemispheres. Its name derives from the fact that it is the largest circle that can be drawn on the surface of a sphere. See also celestial equator, meridian. greenhouse effect The process by which atmospheric gases make the surface of a planet hotter than would be the case if the planet had no atmosphere. Incoming sunlight is absorbed at the surface of a planet and reradiated as infrared radiation, which is then absorbed by greenhouse gases such as carbon dioxide, water vapor, and methane. Part of this trapped radiation is reradiated back down toward the ground, so raising its temperature.

H HII region A glowing region of ionized hydrogen surrounding one or more hot, highly luminous stars. An HII region is often just a part of a more extensive cloud of gas and dust, the remainder of which has not been ionized and is not shining. See also ion, nebula. halo A spherical region surrounding a galaxy that contains a distribution of globular clusters, thinly scattered stars, and some gas. A dark-matter halo is a distribution of dark matter within which a galaxy is embedded. heliocentric (1) Treated as being viewed from the center of the Sun. (2) Having the Sun at the center (of a system). Heliocentric coordinates specify the position of an object as seen from the center of the Sun. A body that is revolving round the Sun follows a heliocentric orbit. Heliocentric cosmology is a model of the universe, such as the one proposed in 1543 by Nicolaus Copernicus, in which the planets revolve around a central Sun. heliosphere The region of space around the Sun within which the solar wind and interplanetary magnetic field are confined by the pressure of the interstellar medium. Its boundary is called the heliopause. See also interstellar medium, solar wind. helium burning The generation of energy by means of fusion reactions that convert helium into carbon and

oxygen. Helium burning takes place in the core of a star that has left the main sequence and become a red giant, and it may occur again, later in a star’s evolution, in a shell surrounding the core. See also fusion, main sequence, red-giant star. Hertzsprung–Russell (HR) diagram A diagram on which stars are plotted as points according to their luminosity and surface temperature. Luminosity (or absolute magnitude) is plotted on the vertical axis, and surface temperature (or spectral type or color) is plotted on the horizontal axis. Astrophysicists use the Hertzsprung–Russell diagram to classify stars. Depending on a star’s position on the diagram, it may be classified as, for example, a mainsequence star, a giant, or a dwarf. Hubble constant see Hubble’s law. Hubble’s law The observed relationship between the red shifts in the spectra of remote galaxies and their distances, which implies that the speeds at which galaxies are receding are directly proportional to their distances. The Hubble constant (or Hubble parameter)—denoted by the symbol H0—is the constant of proportionality that relates speed of recession to distance. hydrogen burning The generation of energy by means of fusion reactions that convert hydrogen into helium. Hydrogen burning takes place in the core of a main-sequence star. When a star has consumed all the available hydrogen in its core, the core contracts and hydrogen burning then continues in a thin shell surrounding the core. See also fusion, main sequence, proton–proton reaction. hypernova see gamma-ray burst.

I impact crater see crater. inclination The angle at which one plane is tilted relative to another. The inclination of a planetary orbit is the angle between its plane and the plane of the ecliptic (the plane of Earth’s orbit). The inclination of a planet’s equator is the angle between the plane of its orbit and the plane of its equator. See also ecliptic, orbit. inferior conjunction see conjunction. inferior planet A planet that travels around the Sun on an orbit that is inside the orbit of Earth. The two inferior planets are Mercury and Venus. See also superior planet. inflation A sudden, short-lived episode of accelerating expansion thought to have occurred at a very early stage in the history of the universe (about 10-35 seconds after the beginning of time). See also Big Bang. infrared radiation Electromagnetic radiation with wavelengths longer than visible light but shorter than microwaves or radio waves. Infrared

is the dominant form of radiation emitted from many cool astronomical objects, such as interstellar dust clouds. See also electromagnetic radiation. interstellar medium The gas and dust that permeates the space between the stars within a galaxy. ion A particle or system of particles with a net electrical charge. Positive ions are commonly formed when an atom loses one or more of its electrons, whereas negative ions result from an excess of electrons. Ions may form from complexes of former atoms. The process by which an atom or complex gains or loses an electron to become charged is called ionization. See also electron, photon. irregular cluster see galaxy cluster. irregular galaxy A galaxy that has no well-defined structure or symmetry. isotope Any one of two or more forms of a particular chemical element, the atoms of which contain the same number of protons but different numbers of neutrons. For example, helium-3 and helium-4 are isotopes of helium; a nucleus of helium-4 (the heavier, and more common, isotope) contains two protons and two neutrons, whereas a nucleus of helium-3 contains two protons and one neutron. See also atom, nucleus.

K Kepler’s laws of planetary motion Three laws, devised in the early 17th century by Johannes Kepler, that describe the orbital motion of planets around the Sun. In essence, the first law states that each planet’s orbit is an ellipse, the second shows that a planet’s speed varies as it travels around its orbit, and the third links its orbital period (the time taken to travel around the Sun) to its average distance from the Sun. Kuiper Belt (Edgeworth–Kuiper Belt) A flattened distribution of icy planetesimals that orbit the Sun at distances in the region of 30–100 times Earth’s distance from the Sun; it is the source of many of the shorterperiod comets. See also Oort Cloud, planetesimal.

L lenticular galaxy A galaxy that is shaped like a convex lens. It has a central bulge that merges into a disk, but no spiral arms. See also galaxy, spiral galaxy. lepton A fundamental particle, such as an electron or a neutrino, that is not acted on by the strong nuclear force. light-year (ly) A unit of distance equal to the distance light travels in one year—5,878 billion miles (9,460 billion km). limb The edge of the observed disk of the Sun, the Moon, or a planet.

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gamma radiation Electromagnetic radiation with extremely short wavelengths (shorter than X-rays) and very high frequencies. Gamma radiation occupies the shortestwavelength region of the spectrum. See also electromagnetic radiation, electromagnetic spectrum. gamma-ray burst (GRB) A sudden burst of gamma radiation from a source in a distant galaxy. Gammaray bursts are the most powerful explosive events in the present-day universe. They may be triggered by collisions between neutron stars or black holes or by an extreme version of a supernova called a hypernova. gas planet (gas giant) A large planet that, like Jupiter or Saturn, consists predominantly of hydrogen and helium. Beneath its thick gaseous atmosphere, the pressure is so great that hydrogen and helium exist in liquid form. See also rocky planet. gegenschein A very faint patch of light that sometimes may be seen on a clear, moonless night in the region of sky directly opposite the position of the Sun. It is caused by sunlight that has been reflected back toward Earth by interplanetary dust particles lying beyond the orbit of Earth. See also zodiacal light. general theory of relativity see relativity. geocentric (1) Treated as being viewed from the center of Earth. (2) Having Earth at the center (of a system). Geocentric coordinates are a system of positional measurements (such as right ascension and declination) that are treated as being measured from the center of Earth. A satellite that is traveling around Earth is in a geocentric orbit. Geocentric cosmology was the ancient theory that the Sun, Moon, planets, and stars revolved around a central Earth. See also heliocentric. giant star A star that is larger and much more luminous than a main-sequence star of the same surface temperature. See also Hertzsprung–Russell diagram, main sequence, red giant. globular cluster A near-spherical cluster of between 10,000 and more than 1 million stars. Globular clusters, which consist of very old stars, are located predominantly in the halos of galaxies. See also open cluster. gravitation see gravity. gravitational lens A massive body, or a distribution of mass (such as a galaxy cluster), whose gravitational field deflects light rays from a more distant background object, thereby acting as a lens to produce a magnified or distorted image, or images, of that background object. gravitational wave A wavelike distortion of space that propagates at the speed of light. Although waves of this kind have not yet been detected directly, there is strong indirect evidence that they exist.

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GLOSSARY Local Group The small cluster of more than 40 member galaxies to which the Milky Way galaxy belongs. The other major members are the spiral galaxies M31 (the Andromeda Galaxy) and M33. Most of the members are small (or dwarf) elliptical or irregular galaxies. See also galaxy cluster. local sidereal time see sidereal time. luminosity The total amount of energy emitted in one second by a source of radiation, such as the Sun or a star. The luminosity of a star can be expressed in watts or in units of solar luminosity (the luminosity of the Sun is 3.8 x 1026 watts). Stars are divided into luminosity classes denoted by Roman numerals. See also magnitude. lunar eclipse see eclipse.

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M MACHO An acronym for MAssive Compact Halo Object, a very lowluminosity object—such as a planet, brown dwarf, exceedingly dim white dwarf, or black hole—that exists in the halo of a galaxy but is usually too faint to be seen directly. MACHOs are believed to account for a relatively small proportion of the unseen dark matter in a galaxy’s halo. See also dark matter, halo. magnetic field The region of space surrounding a magnetized body within which its magnetic influence affects the motion of an electrically charged particle. magnetosphere The region of space around a planet within which the motion of charged particles is controlled by the planetary magnetic field rather than the solar wind and the associated interplanetary magnetic field. The shape of a planet’s magnetosphere is influenced by the solar wind, which squeezes it inward on the Sun-facing side and drags it out to form an elongated “tail” (a magnetotail) on the opposite, or downstream, side. See also solar wind. magnification The increase in the apparent angular size of an object when viewed through an optical instrument, such as a telescope. The magnification of a telescope is equal to the focal length of its objective lens or primary mirror divided by the focal length of its eyepiece. magnitude (absolute and apparent) Apparent magnitude is a measure of the apparent brightness of an object as seen in the sky. The fainter the object, the higher the numerical value of its magnitude. The faintest stars visible to the naked eye are of magnitude 6, whereas the brightest objects in the sky have negative apparent magnitudes. A star said to be of 1st magnitude has a magnitude of 1.49 or less, a star of 2nd magnitude has a value of 1.50 to 2.49, and so on. Absolute magnitude is the apparent magnitude a star would have if it

were located at a standard distance of 10 parsecs (32.6 light-years) from Earth. See also luminosity, parsec. Main Belt see asteroid. main sequence A band that slopes diagonally from the upper left (hot, high-luminosity region) to the lower right (cool, low-luminosity region) of the Hertzsprung–Russell diagram and contains about 90 percent of stars. Main-sequence stars, such as the Sun, shine by converting hydrogen in their cores to helium. See also dwarf star, Hertzsprung–Russell diagram. major axis see ellipse. mantle The rocky layer that lies between the core and the crust of a rocky (Earth-like) planet or a major planetary satellite. See also core, crust. mare (plural: maria) A relatively smooth, dark, lava-filled basin on the surface of the Moon. The name derives from the Latin for “sea.” massive compact halo object see MACHO. meridian (1) A great circle on the surface of Earth or another astronomical body that passes through the north and south poles and crosses the equator at right angles. (2) A great circle on the celestial sphere that passes through the north and south celestial poles and crosses the celestial equator at right angles. An observer’s local meridian passes through the celestial pole, the zenith, and the north and south points of the horizon. See also celestial sphere, great circle. Messier catalog A widely used catalog of nebulous objects (most of them nebulae, star clusters, and galaxies) that was published in 1781 by the French astronomer Charles Messier. Objects contained in this catalog are designated by the letter “M” followed by a number. For example, M31 is the Andromeda Galaxy and M42 is the Orion Nebula. See also New General Catalog. meteor The short-lived streak of light seen when a meteoroid plunges into Earth’s atmosphere and is heated to incandescence by friction. A sporadic meteor is one that appears at a random time from a random direction. A meteor shower is a substantial number of meteors that appear to radiate from a common point in the sky (the radiant) when Earth is passing through a stream of meteoroids. See also meteorite, meteoroid. meteorite A rocky or metallic meteoroid that survives passage through the atmosphere and reaches Earth’s surface in one piece or in fragments. See also meteor, meteoroid. meteoroid A lump or small particle of rock, metal, or ice orbiting the Sun in interplanetary space. Sizes of meteoroids range from a small fraction of an inch (a fraction of a millimeter) to a few yards (meters). Some are debris from collisions between asteroids. Others are particles released by comets; these spread out along cometary orbits to

form meteoroid streams. See also asteroid, comet, meteor, meteorite. Milky Way (1) The spiral galaxy that contains the Sun, sometimes also referred to as the Milky Way galaxy or the Galaxy. (2) A faint, misty band of light that stretches across the night sky and consists of the combined light of vast numbers of stars and nebulae that lie in the disk and spiral arms of our galaxy. See also galaxy. Mira variable A class of long-period variable stars named after the star Mira—Omicron (o) Ceti—in the constellation Cetus. Mira variables are cool, giant pulsating stars that vary in brightness over periods ranging from 100 days to more than 500 days. See also variable star. molecular cloud A cool, dense cloud of gas and dust in which the temperature is sufficiently low to enable atoms to join together to form molecules such as molecular hydrogen (H2) or carbon monoxide (CO), and within which conditions are favorable for star formation. moon Also known as a natural satellite, a body that orbits a planet. The Moon is Earth’s natural satellite. Orbiting Earth at a mean distance of 239,000 miles (384,000 km) in a period of 27.3 days, it has a diameter of 2,159 miles (3,476 km). See also satellite. moon dog See sun dog. multiple star A system consisting of two or more stars bound together by gravity and revolving around each other (a system of just two stars is also called a binary). See also binary star.

N near-Earth asteroid see asteroid. nebula (plural: nebulae) A cloud of gas and dust in interstellar space. The name derives from the Latin for “cloud.” There are several types of luminous nebula (nebulae that shine). An emission nebula is a cloud of gas and dust that contains one or more extremely hot, young, highluminosity stars; ultraviolet light emitted by these stars causes the surrounding gas to glow. Nebulae of this kind are also called HII regions because they contain a large proportion of ionized hydrogen. A reflection nebula is observed when the dust particles within a cloud are lit up by light from a neighboring bright star. Other types of luminous nebulae include planetary nebulae (shells of gas puffed out by dying stars) and supernova remnants (the debris of exploded stars). A dark nebula (or absorption nebula) is a dustladen cloud that blocks out light from background stars and appears as a dark patch in the sky. See also diffuse nebula, HII region, planetary nebula, supernova. neutrino A fundamental particle of exceedingly low mass, which has zero

electrical charge and which travels at very close to the speed of light. neutron A particle, composed of three quarks, that has zero electrical charge and a mass fractionally greater than that of a proton. Neutrons are found in the nuclei of atoms. See also atom. neutron star An exceedingly dense, compact star that is composed almost entirely of tightly packed neutrons. A typical neutron star has a diameter of around 6 miles (10 km) yet has about the same mass as the Sun. A neutron star forms when the core of a highmass star collapses, triggering a supernova explosion. See also pulsar, supernova. New General Catalog (NGC) A catalog of nebulae, clusters, and galaxies that was published in 1888 by the Danish astronomer John L. E. Dreyer. Objects in this catalog are denoted by “NGC” followed by a number. For example, the Andromeda Galaxy is NGC 224. See also Messier catalog. Newton’s laws of motion Three laws describing the behavior of moving bodies that were set out by Isaac Newton in 1687. Newton’s first law states that a body continues to move in a straight line at a constant speed unless acted on by a force. The second law shows how a force causes a body to accelerate in the direction along which an applied force is acting. The third law states that for any force there is an equal and opposite reaction force. Newtonian gravity see gravity. nova (plural: novae) A star that suddenly brightens by a factor of thousands or more, then fades back to its original brightness over a period of weeks or months. The flareup occurs when a fusion reaction is triggered on the surface of a white dwarf by gas flowing from a companion star. The name derives from the Latin for “new,” because the rapid brightening produces what appears to be a new star. See also white dwarf, fusion. nuclear bulge see spiral galaxy. nuclear fusion see fusion. nucleus (plural: nuclei) (1) The compact central core of an atom, which consists of a number of positively charged protons and neutral neutrons. The nucleus of a hydrogen atom consists of a single proton. (2) The solid, ice-rich body of a comet. (3) The central core of a galaxy, within which stars are relatively densely packed together.

O occultation The passage of one body in front of another, which causes the more distant one to be wholly or partially hidden. The term is usually used to describe the passage of a body of larger apparent size in front of a body of smaller apparent size—

GLOSSARY for example, when the Moon passes in front of a star or when a planet (such as Jupiter) passes in front of one of its moons. Oort Cloud (Oort–Öpik Cloud) A spherical distribution of trillions of icy planetesimals and cometary nuclei that surrounds the solar system and extends out to a radius of about 1.6 light-years from the Sun. It provides the reservoir from which long-period and “new” comets originate. Its existence was proposed in 1950 by Dutch astronomer Jan H. Oort (a similar idea had also been suggested by Estonian astronomer Ernst J. Öpik). See also comet, planetesimal. open cluster A loose cluster of up to a few thousand stars that lies in or close to the plane of the Milky Way galaxy. Member stars of each cluster formed from the same cloud of gas and dust, and have closely similar ages and chemical compositions. Clusters of this kind are also known as galactic clusters. See also globular cluster. open universe A universe in which the average density is less than the critical density that is needed to halt its expansion and which, therefore, will expand forever. See also closed universe, flat universe, oscillating universe. opposition The position of a planet when it is exactly on the opposite side of Earth from the Sun. Its elongation is then 180°, and it is highest in the sky at midnight. See also conjunction, elongation. optical double star see double star. orbit The path of a body that is moving within the gravitational field of another. The orbit of a planet around a star or a satellite around a planet will normally be an ellipse or, exceptionally, a circle (a circle is a special case of an ellipse). orbital period The period of time during which a body travels once around its orbit. The sidereal orbital period is the time taken by one body to revolve around another (for example, the Moon around Earth) measured relative to the background stars. oscillating universe A universe that expands and contracts in a cyclic fashion. The collapse of such a universe at the end of one cycle triggers a new Big Bang that initiates the next cycle. See closed universe, flat universe, open universe.

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prominence A flamelike plume of gas that follows magnetic field lines in the solar atmosphere. An active or eruptive prominence undergoes rapid changes, whereas a quiescent prominence remains suspended in the solar atmosphere for a prolonged period. proper motion The angular rate at which a star changes its observed position on the celestial sphere. Annual proper motion is the angle (seldom more than a small fraction of 1 second of angular measurement) through which a star appears to shift in the course of one year. protogalaxy A progenitor of a normal galaxy. The building blocks from which galaxies were assembled through a process of collisions and mergers, protogalaxies are believed to have formed a few hundred million years after the Big Bang when clouds of gas collapsed under the action of gravity. proton An elementary particle, composed of three quarks, that has a positive electrical charge and is a constituent of every atomic nucleus. See also atom. proton–proton chain (pp chain) A sequence of reactions that fuse together hydrogen nuclei (protons) to create helium nuclei. The net result of the process is to convert four protons into one helium nucleus, which consists of two protons and two neutrons. The proton–proton reaction is the dominant hydrogenburning process in stars similar to, or less massive than, the Sun. See also fusion, hydrogen burning, neutron, proton. protoplanetary disk A flattened disk of dust and gas surrounding a newly formed star and within which matter may be aggregating together to form the precursors of planets. See also planetesimal. protostar A star in the early stages of formation. It consists of the central part of a collapsing cloud that is heating up and is accreting matter from its surroundings, but within which hydrogen fusion reactions have not yet commenced. pulsar A rapidly rotating neutron star from which we receive brief pulses of radiation, at short and precisely timed intervals, as it spins around its axis. pulsating variable see variable star.

Q quantum see photon. quark A fundamental particle, the main matter constituent of all atomic nuclei. Quarks join in bunches of three to make baryons (for example, protons and neutrons) or in quark–antiquark pairs to form particles called mesons. See also antiparticle, baryon. quasar A very compact but extremely powerful source of radiation that is almost starlike in appearance but is

believed to be the most luminous kind of active galactic nucleus. The name is an abbreviation for quasistellar radio source, but is also applied to quasi-stellar objects (QSOs), which are not strong radio emitters. quiescent prominence see prominence.

R radial velocity The component of a body’s velocity that is along the line of sight directly toward, or away from, an observer. The radial velocity of a celestial body can be obtained by measuring the Doppler effect in its spectrum. See also Doppler effect, red shift, spectrum. radiant The point in the sky from which the tracks of meteors that are members of a particular meteor shower appear to radiate. See also meteor. radio galaxy A galaxy that is exceptionally luminous at radio wavelengths. A typical radio galaxy contains an active galactic nucleus from which jets of energetic charged particles are being propelled toward huge clouds of radio-emitting material that in many cases are much larger than the visible galaxy. See also active galaxy. radio telescope An instrument that is designed to detect radio waves from astronomical sources. The most familiar type is a concave dish that collects radio waves and focuses them onto a detector. red dwarf star A cool, red, lowluminosity star that, when plotted on a Hertzsprung–Russell diagram, is located toward the bottom end of the main sequence. See also Hertzsprung–Russell diagram, main sequence. red-giant star A large, highly luminous star with a low surface temperature and a reddish color. A red giant has evolved away from the main sequence, is “burning” helium in its core rather than hydrogen, and is approaching the final stages of its life. See also helium burning, Hertzsprung–Russell diagram, main sequence. red shift The displacement of spectral lines to longer wavelengths that is observed when a light source is receding from an observer. The shift in wavelength is proportional to the speed at which the source is receding. Cosmological red shift is a wavelength shift that is caused by the expansion of the universe. See also blue shift, Doppler effect, spectral line. red supergiant star An extremely large star of very high luminosity and low surface temperature. Stars of this kind are located toward the top-right corner of the Hertzsprung–Russell diagram. See also Hertzsprung–Russell diagram.

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parallax The apparent shift in position of an object when it is observed from different locations. Stellar parallax is the apparent shift in position of a relatively nearby star when viewed from different points on Earth’s orbit. Annual parallax is the maximum angular displacement of a star from its mean position due to parallax. The greater the distance of a star, the smaller its parallax.

parhelic circle See sun dog. parsec (pc) The distance at which a star would have an annual parallax of one second of arc (one second of angular measurement). One parsec is equivalent to 3.26 light-years, or 19,200 billion miles (30,900 billion km). See also parallax. parselene See sun dog. penumbra (1) The lighter, outer part of the shadow cast by an opaque body. An observer within the penumbra can see part of the illuminating source. See also eclipse. (2) The less dark and less cool outer region of a sunspot. See also sunspot, umbra. perigee The point on its orbit at which a body that is revolving around Earth is at its closest to Earth. See also apogee. perihelion The point on its orbit at which a planet, or other solar system body, is at its closest to the Sun. phase The proportion of the visible hemisphere of the Moon or a planet that is illuminated by the Sun at any particular instant. photon An individual package, or quantum, of electromagnetic energy, which may be envisaged as a “particle” of light. The shorter the wavelength of the radiation and higher the frequency, the greater the energy of the photon. See also electromagnetic radiation. photosphere The thin, gaseous layer at the base of the solar atmosphere, from which the Sun’s visible light is emitted and which corresponds to the visible surface of the Sun. planet A body that is much less massive than a star, revolves around a star, and shines by reflecting that star’s light. As a general guide, an orbiting body is considered to be a planet (rather than a brown dwarf) if its mass is less than about 13 times the mass of Jupiter. See also brown dwarf star. planetary nebula A glowing shell of gas ejected by a star at a late stage in its evolution. planetesimal One of the large number of small bodies, composed of rock or ice, that formed within the solar nebula and from which the planets were eventually assembled through the process of accretion. plasma A completely ionized gas state of matter that consists of equal numbers of positively charged ions and negatively charged electrons. Plasmas usually have very high temperatures. Examples include the solar corona and solar wind, both of which consist predominantly of protons and electrons. See also corona, solar wind. polar axis see equatorial mounting. positron see antiparticle. precession A slow change in the orientation of a rotating body’s axis caused by the gravitational influence of neighboring bodies. Earth’s axis precesses around in a conical pattern over a period of 25,800 years.

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GLOSSARY reflecting telescope (reflector) A telescope that uses a concave mirror to collect light, reflect light rays to a focus, and form an image of a distant object. reflection nebula see nebula. refracting telescope (refractor) A telescope that uses a lens to refract (bend) light rays in order to bring them to a focus and form an image of a distant object. regolith A layer of loose rock, rocky fragments, and dust that covers the surface of a planet or planetary satellite. regular cluster see galaxy cluster. relativity Theories developed in the early part of the 20th century by Albert Einstein to describe the nature of space and time and the motion of matter and light. The special theory of relativity describes how the relative motion of observers affects their measurements of mass, length, and time. One of its consequences is that mass and energy are equivalent. The general theory of relativity treats gravity as a distortion of space-time associated with the presence of matter or energy. One of its consequences is that massive bodies deflect rays of light. See also gravitational lensing, space-time. resonance A gravitational interaction between two orbiting bodies that occurs when the orbital period of one is an exact, or nearly exact, simple fraction of the orbital period of the other. For example, Jupiter’s moon Io is in a 1:2 resonance with another of Jupiter’s moons, Europa (Io’s period is half of Europa’s period). When a small object is in resonance with a more massive one, it experiences a periodic gravitational tug each time one of the bodies overtakes the other, the cumulative effect of which gradually changes its orbit. retrograde motion (1) The apparent backward motion of a planet, from east to west relative to the background stars. For most of the time, a planet such as Mars or Jupiter will move from west to east relative to the stars (direct motion), but it will appear to reverse direction each time it is being overtaken by Earth (around the time of opposition). See also opposition. (2) Orbital motion in the opposite direction of that of Earth and the other planets of the solar system. (3) The motion of a satellite along its orbit in the opposite direction to that in which its parent planet is rotating. retrograde rotation The rotation of a body around its axis in the opposite direction to the rotational motion of Earth, the Sun, and the majority of the planets.Viewed from above its North Pole, Earth rotates around its axis and revolves around the Sun, in a counterclockwise direction (direct rotation), whereas a planet with retrograde rotation spins in the

opposite (clockwise) direction. The planets Venus, Uranus, and Pluto exhibit retrograde rotation. rich cluster see galaxy cluster. right ascension (RA) The angular distance, measured eastward, between the first point of Aries (where the Sun’s path around the sky crosses the celestial equator from south to north) and a celestial body. It is expressed in hours, minutes, and seconds of time, where 1 hour is equivalent to an angle of 15°. Together with declination, it specifies the position of a body on the celestial sphere. See also celestial sphere, declination, ecliptic, equinox. ring A flat distribution of small particles and lumps of material that revolves around a planet, usually in the plane of its equator. A ring system consists of a number of concentric rings surrounding a planet. The planets Jupiter, Saturn, Uranus, and Neptune each have a ring system. rocky planet A planet (also called a terrestrial planet) that is composed mainly of rocks and has basic characteristics similar to Earth. Within the solar system, there are four rocky planets: Mercury, Venus, Earth, and Mars. See also gas planet. rupes Scarps or cliffs on the surface of a planet or a satellite. See also moon.

S satellite A body that revolves around a planet, otherwise known as a “moon.” An artificial satellite is an object deliberately placed in orbit around Earth or around another solar system body. Schmidt–Cassegrain telescope A type of catadioptric telescope. Light enters the telescope tube through a thin corrector lens and is reflected from a concave mirror at the bottom of the tube toward a small convex mirror fixed to the inner face of the correcting lens. It is then reflected back down the tube, through a hole in the concave mirror, to a focus. This is a popular, compact design for small and moderate-sized telescopes. See also catadioptric telescope. Schwarzschild radius see black hole. semimajor axis see ellipse. Seyfert galaxy A spiral galaxy with an unusually bright, compact nucleus that in many cases exhibits brightness fluctuations. First identified by American astronomer Carl Seyfert in 1943, Seyfert galaxies comprise one of the several categories of active galaxies. See also active galaxy. shepherd moon A small natural satellite that, through its gravitational influence, confines orbiting particles into a well-defined ring around a planet. A pair of shepherd moons, where one is slightly closer to the planet than the other, can squeeze particles into particularly narrow rings.

sidereal orbital period see orbital period. sidereal time A time system based on the apparent rotation of the celestial sphere. Local sidereal time is defined to be 0 hours at the instant the first point of Aries crosses an observer’s meridian. The sidereal day corresponds to Earth’s axial rotation period measured relative to the background stars, and is equal to 23 hours 56 minutes 4 seconds of mean (civil) time. See also equinox, right ascension. singularity A point of infinite density into which matter has been compressed by gravity, and a point at which the known laws of physics break down. Theory implies that a singularity exists at the center of a black hole. See also black hole. solar cycle A cyclic variation in solar activity (for example, the production of sunspots and flares), which reaches a maximum at intervals of about 11 years. Because the polarity pattern of magnetic regions on the Sun reverses every 11 years or so, the overall duration of the cycle is 22 years. The sunspot cycle is the 11-year variation in the number (and overall area) of sunspots. See also solar flare, sunspot. solar eclipse see eclipse. solar flare A violent release of huge amounts of energy—in the form of electromagnetic radiation, subatomic particles, and shock waves—from a site located just above the surface of the Sun. solar mass A unit of mass equal to the mass of the Sun, which provides a convenient standard for comparing the masses of stars. One solar mass is equivalent to 1.96 x 1027 tons (1.989 x 1030 kg). Stellar masses range from about 0.08 solar masses up to about 100 solar masses. solar nebula The cloud of gas and dust from which the Sun and planets formed. As the cloud collapsed, most of its mass accumulated at the center to form the Sun, whereas the rest flattened out into a disk within which planets were assembled by the process of accretion. See also accretion, protoplanetary disk. solar system The Sun together with everything that revolves around it (the planets and their satellites, asteroids, comets, meteoroids, gas, and dust). solar wind A stream of fast-moving, charged particles (predominantly electrons and protons) that escapes from the Sun and flows outward through the solar system like a wind. solstice One of the two points on the ecliptic at which the Sun is at its maximum declination north or south of the celestial equator. On or around June 21 each year, the Sun reaches its greatest northerly declination. This is the Northern Hemisphere summer solstice (the winter solstice in the Southern Hemisphere). On or around December 22 each year, the

Sun reaches its greatest southerly declination. This is the Northern Hemisphere winter solstice (the summer solstice in the Southern Hemisphere). See also celestial equator, declination, ecliptic. space-time The four-dimensional combination of the three dimensions of space (length, breadth, and height) and the dimension of time. The concept that time and space are intimately linked, rather than (as Newton had believed) being separate entities, was proposed in 1908 by Hermann Minkowski and was incorporated into Albert Einstein’s theories of relativity. See also relativity. special theory of relativity see relativity. spectral line A feature that appears at a particular wavelength in a spectrum. An emission line is a bright feature corresponding to the emission of light at that wavelength, whereas an absorption line is a dark feature corresponding to the absorption of light at that wavelength. See also spectrum. spectral type A class into which a star is placed according to the lines that appear in its spectrum. The principal spectral types, arranged in decreasing order of temperature, are labeled O, B, A, F, G, K, M and are subdivided into numbers from 0 to 9. For example, the spectral type of the Sun is G2. See also luminosity, spectral line, spectrum. spectroscopic binary see binary star. spectroscopy The science of obtaining and studying the spectra of objects. Because the detailed appearance of a spectrum is influenced by factors such as chemical composition, density, temperature, rotation, velocity, turbulence, and magnetic fields, spectroscopy can reveal a wealth of information about the physical and chemical properties of, and processes occurring in, planets, stars, gas clouds, galaxies, and other kinds of celestial bodies. See also spectrum. spectrum A beam of electromagnetic radiation spread out into its constituent wavelengths. A continuous spectrum is the unbroken spread of wavelengths emitted by a hot solid or liquid or a dense gas (the continuous spectrum of sunlight appears to human eyes as a rainbow band of colors). A hot, low-density gas emits light at particular wavelengths only; the resulting spectrum consists of bright emission lines, each of which corresponds to one of the wavelengths at which emission takes place. If a low-density gas is silhouetted against a source of a continuous spectrum, it absorbs light at certain wavelengths to produce a series of dark absorption lines. A typical star has an absorption-line spectrum (a continuous spectrum with dark lines superimposed by its atmosphere), whereas an emission nebula has an emission-line spectrum. See also spectral line.

GLOSSARY Saturn, Uranus, Neptune, and Pluto. See also inferior planet. supermassive black hole see black hole. supernova (plural: supernovae) A catastrophic event that destroys a star and causes its brightness to increase, temporarily, by a factor of around 1 million. A type II supernova occurs when the core of a massive star collapses and the rest of the star’s material is blasted away; the collapsed core usually becomes a neutron star. A type Ia supernova involves the complete destruction of a white dwarf. The expanding cloud of debris from a supernova is called a supernova remnant. See also neutron star, white dwarf. synchrotron radiation Electromagnetic radiation that is emitted when electrically charged particles (usually electrons) gyrate at very high speed around lines of force in a magnetic field. Synchrotron radiation has a characteristic continuous spectrum that is different from that which is emitted by a star or a black body. Astronomical sources of synchrotron radiation include supernova remnants and radio galaxies. See also black body, electromagnetic radiation, spectrum. synchronous rotation The rotation of a body around its axis in the same period of time that it takes to orbit another body. Synchronous rotation, which is also known as captured rotation, is caused by tidal forces acting between the two bodies. Because its rotational and orbital periods are the same, the orbiting body always keeps the same face turned toward the object around which it is revolving. Like most of the planetary satellites, Earth’s moon displays synchronous rotation. See also orbital period, satellite.

T tail (of a comet) A stream, or streams, of ionized gas and dust that is swept out of the head of a comet (the coma) when it approaches, and begins to recede from, the Sun. A type I tail (or gas tail) consists of ionized gas driven out of the coma by the solar wind. A type II tail (or dust tail) is composed of dust particles that have been swept out of the coma by the pressure of sunlight. See also comet. tectonic plate One of the large, rigid sections into which Earth’s lithosphere (which comprises the crust and the rigid uppermost layer of Earth’s mantle) is divided. Carried along by slow convection currents in the mantle, tectonic plates drift very slowly across the surface of the planet. Their relative motions give rise to phenomena such as earthquakes, volcanic activity, and mountain-building. The term “tectonic” is sometimes also used

to refer to large-scale geological structures, and features resulting from their movement, on planets other than Earth. See also convection, crust, mantle. tektite A small, rounded, glassy object formed when a large meteorite or asteroid strikes a rocky planet, melting the surface rocks and throwing molten drops of rock into the atmosphere. Typically a few inches (centimeters) across, tektites have been shaped by their flight through the atmosphere. On Earth’s surface, they are found in a number of specific locations, called strewn fields. See also asteroid, meteorite. terrestrial planet see rocky planet. transit (1) The passage of a particular celestial body across an observer’s meridian. (2) The passage of a body in front of a larger one (for example, the passage of the planet Venus across the face of the Sun, or a satellite across the face of a planet). T Tauri star A young star, surrounded by gas and dust, that varies in brightness and usually shows evidence of a strong stellar wind (a stream of gas flowing away from the star). T Tauri stars are believed still to be contracting toward the main sequence. They are named after the first star of this kind to be identified. See also main sequence, protostar.

UV ultraviolet radiation Electromagnetic radiation with wavelengths shorter than visible light but longer than X-rays. The hottest stars radiate strongly at ultraviolet wavelengths. umbra (1) The dark, central cone of the shadow cast by an opaque body. The illuminating source will be completely hidden from view at any point within the umbra. (2) The darker, cooler central region of a sunspot, where the temperature is about 2,700–3,600°F (about 1,500–2,000°C) cooler than the average for the solar surface. See also eclipse, penumbra, sunspot. vacuum energy see cosmological constant. Van Allen belts Two concentric doughnut-shaped zones that contain charged particles (electrons and protons) trapped in Earth’s magnetic field. They were discovered in 1958 by American space scientist James Van Allen. variable star A star that varies in brightness. A pulsating variable is a star that expands and contracts in a periodic way, varying in brightness as it does so. An eruptive variable is a star that brightens and fades abruptly. A cataclysmic variable is a star that suffers one or more major explosions (for example, a nova). See also Cepheid variable, nova. vernal equinox see equinox. volcanic crater see crater.

W wavelength The distance between two successive crests or between two successive troughs in a wave motion. WIMP The acronym for Weakly Interacting Massive Particle, one of a range of postulated elementary particles that have high masses (tens or hundreds of times as great as that of a proton) but interact so exceedingly weakly with ordinary matter that they have not yet been directly detected. WIMPs are widely considered to comprise the major part of the dark-matter content of the universe. See also dark matter. white dwarf star A star of low luminosity but relatively high surface temperature that has ceased to generate energy by nuclear-fusion reactions, that has been compressed by gravity to a diameter comparable to that of Earth, and that is slowly cooling and fading. See also black dwarf, Hertzsprung–Russell diagram. Wolf–Rayet star A very hot star from which gas is escaping at an exceptionally rapid rate, which is surrounded by an expanding gaseous envelope, and which has emission lines in its spectrum. See also emission line, spectrum.

XYZ X-ray burster An object that emits strong bursts of X-rays, lasting from a few seconds to a few minutes. The bursts are believed to occur when gas drawn from an orbiting companion star accumulates on the surface of a neutron star and triggers a nuclearfusion chain reaction. See also fusion, neutron star. X-ray radiation Electromagnetic radiation with wavelengths shorter than ultraviolet radiation but longer than gamma rays. X-rays are emitted by extremely hot clouds of gas, such as the solar corona. zenith The point on the sky directly above an observer (that is, 90° above the observer’s horizon). zodiac A band around the celestial sphere that extends for 9° on either side of the ecliptic, and through which the Sun, Moon, and nakedeye planets appear to travel. The zodiac contains part or all of 24 constellations. In the course of the year, the Sun passes through 13 of these constellations, 12 of which correspond to the astrological “signs of the zodiac.” See also ecliptic. zodiacal light A faint, cone-shaped glow that extends along the direction of the ecliptic from the western horizon after sunset or from the eastern horizon before sunrise. Most easily seen from tropical skies, it is caused by the scattering of sunlight by particles of interplanetary dust that lie close to the plane of the ecliptic.

G L OS S A RY

spiral arm A spiral-shaped structure extending outward from the central bulge of a spiral or barred spiral galaxy. It consists of gas, dust, emission nebulae, and hot young stars, spiral galaxy A galaxy that consists of a spheroidal central concentration of stars (the nuclear bulge) surrounded by a flattened disk composed of stars, gas, and dust, within which the major visible features are clumped together into a pattern of spiral arms. See also galaxy, spiral arm. star A self-luminous body of hot plasma that generates energy by means of nuclear fusion reactions. starburst galaxy A galaxy within which star formation is taking place at an exceptionally rapid rate. star cluster A group of between a few tens and around 1 million stars held together by gravity. All the member stars of a particular cluster are thought to have formed from the same original massive cloud of gas and dust. There are two principal types of cluster: open clusters and globular clusters. See also globular cluster, open cluster. stellar-mass black hole see black hole. stellar parallax see parallax. stellar wind An outflow of charged particles from the atmosphere of a star. See also solar wind. sun dog One of a pair of colored patches of light that sometimes may be seen on either side of the Sun, separated from the Sun by an angle of about 22°. Otherwise known as a parhelion or mock sun, a sun dog is formed when ice crystals in Earth’s atmosphere refract sunlight. A moon dog, or parselene, is a patch of light that sometimes forms by the same process on either side of the Moon. A parhelic circle is a large, faint ring of white light, produced by the reflection of sunlight from atmospheric ice crystals, which crosses the Sun, passes through a pair of sundogs, and extends around the sky. Although a complete circle may be seen occasionally, more usually it is only possible to see arcs of light extending outward from the sundogs. sunspot A patch on the surface of the Sun that appears dark because it is cooler than its surroundings. Sunspots occur in regions where localized concentrated magnetic fields impede the outward flow of energy from the solar interior. See also solar cycle. supergiant An exceptionally luminous star with a very large diameter. Supergiant stars appear at the top of the Hertzsprung–Russell diagram. See also Hertzsprung–Russell diagram. superior conjunction see conjunction. superior planet A planet that travels around the Sun on an orbit that is outside the orbit of Earth. The superior planets are Mars, Jupiter,

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INDEX

INDEX Page numbers in bold indicate feature profiles or extended treatments of a topic. Page numbers in italic indicate pages on which the topic is illustrated. 1 Ceres 170, 171, 175 1ES 1853-37.9 268 2dFGRS 339 2MASS (Two–micron All Sky Survey) 340–41 2M1207 297 3C 31 320 3C 48 325 3C 273 325, 378 3C 279 320 3C 405 (Cygnus A) 324 4 Vesta 170, 174 9 Sagittarii 243 15 Monocerotis 280 21 Lutetia 172 24 Tau (τ) 277 30 Doradus see Tarantula Nebula 47 Tucanae (NGC 104) 294, 311, 418, 418, 479, 485, 491 55 Cancri A 298 61 Cygni 252 243 Ida 100, 170, 173 253 Mathilde 172 433 Eros 13, 170, 172, 176–77 951 Gaspra 172 1992 QB1 208 2867 Steins 172 4179 Toutatis 172 5535 Annefrank 172 25143 Itokawa 175

I ND E X

A

A stars 233 AASTO project 305 AB Aurigae 235 Abell, George 333 Abell S 373 (Fornax Cluster) 329 Abell 400 327 Abell 1060 (Hydra Cluster) 332 Abell 1656 (Coma Cluster) 326, 327, 332 Abell 1689 27, 326, 333 Abell 2029 327 Abell 2065 (Corona Borealis Cluster) 333 Abell 2125 333 Abell 2151 (Hercules Cluster) 333, 364 Abell 2218 23, 334–35 absolute magnitude 233 absolute magnitude scale 71 Hertzsprung–Russell (H–R) diagram 232 main-sequence stars 251 absorption lines 35, 35 Lyman Alpha lines 338, 338 stellar classification 233 accelerating motion 42, 42, 339 accretion disks 247 black holes 267, 320 young stars 239 acetylene, on Jupiter 180

Achernar (Alpha (α) Eridani) 250, 406, 420 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 437, 473, 479, 485, 491, 497 Acheron Fossae (Mars) 160 Acidalia Planum (Mars) 162 Acrux (Alpha (α) Crucis) 412, 455 active galaxies 320–25 BL Lacertae 325 Centaurus A 322 Circinus Galaxy 322 Cygnus A 324 Fried Egg Galaxy 323 M87 330–31, 323 NGC 1275 324 NGC 4261 323 NGC 5548 323 PKS 2349 325 “supermassive” black holes 305, 305, 307 types of 320 3C 48 325 3C 273 325 Active Region 1429, Sun 108–109 Adams ring (Neptune) 205, 205 adaptive optics 91, 91 Addams, Jane 123 Addams Crater (Venus) 123 Adonis 171 Adrastea 180, 182 AE Aurigae 408 Aegaeon 191 Aegir 191 Aeneas Crater (Dione) 195 aerogel 217, 217 age of star clusters 289 of Universe 44 Aglaonice Crater (Venus) 123 Air Pump see Antlia Airy Crater (Mars) 163 Aitken Basin Crater (Moon) 140, 149 Aitne 181 Akna Montes (Venus) 118 Albiorix 191 Albireo (Beta (β) Cygni) 366, 366, 472 Alcmene 227 Alcor (80 Ursae Majoris) 276, 360, 361, 454 Alcott Crater (Venus) 123 Alcyone (Eta (η) Tauri) 277, 291, 372 Aldebaran (Alpha (α) Tauri) 256, 372 classification 233 Hertzsprung–Russell (H–R) diagram 232 and Hyades 290 in monthly sky guides 431, 491 naked-eye astronomy 77 Aldrin, Edwin “Buzz” 144 algae 57 Algieba (Gamma (γ) Leonis) 377, 377

Algol (Beta (β) Persei) 276, 370, 370, 496 ALH 81105 meteorite 223 aliens, search for 57, 57 alignments, planetary 69 Alioth (Epsilon (ε) Ursae Majoris) 72, 360 Alkaid (Eta (η) Ursae Majoris) 72, 360 Allende meteorite 222 ALMA, Atacama Large Millimeter Array 92–93, 317 Almaak (Gamma (γ) Andromedae) 277, 368 Almaaz (Epsilon (ε) Aurigae) 281, 283, 283, 359 Almach (Gamma (γ) Andromedae) 277, 368 Alnath (Beta (β) Tauri) 232, 359, 372 Alnilam (Epsilon (ε) Orionis) 232 Alnitak (Zeta (ζ) Orionis) 232, 390, 391, 391 Alpha (α) Andromedae (Alpheratz) 368, 386 Alpha (α) Aquilae (Altair) 252, 366, 383, 383 in monthly sky guides 461, 472, 473, 478, 479, 485 naked-eye astronomy 77 Alpha (α) Arietis 371 Alpha (α) Aurigae (Capella) 359 sky guides 430, 431, 448, 484 Alpha (α) Boötis (Arcturus) 360, 363 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 442, 448, 449, 454, 455, 460, 461, 466, 467, 472 naked-eye astronomy 77 Alpha (α) Canis Majoris (Sirius A) 252, 392 apparent magnitude 71 binary system 274 classification 233 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 430, 431, 437, 442, 443, 491, 497 naked-eye astronomy 77 name, origin of 72 Winter Triangle 436, 436, 496 Alpha (α) Canis Minoris (Procyon) 284, 392 classification 233 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 436, 497 naked-eye astronomy 77 Winter Triangle 436, 436, 496 Alpha (α) Canum Venaticorum (Cor Caroli) 362, 362 Alpha (α) Capricorni 403 Alpha (α) Centauri (Rigil Kentaurus) 252, 274, 398, 398 apparent magnitude 71

Alpha (α) Centauri cont. Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 443, 448, 449, 455, 455, 467, 473, 479 Alpha (α) Ceti (Menkar) 389 Alpha (α) Circini 413 Alpha (α) Corona Borealis (Alpheca) 460 Alpha (α) Corvi 397 Alpha (α) Crucis (Acrux) 412, 455 Alpha (α) Cygni (Deneb) 366 Hertzsprung–Russell (H–R) diagram 232 luminosity 233 in monthly sky guides 460, 467, 472, 473, 478, 479 naked-eye astronomy 77 Alpha (α) Delphini (Sualocin) 385 Alpha (α) Eridani (Achernar) 250, 406, 420 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 437, 473, 479, 485, 491, 497 Alpha (α) Fornacis 405 Alpha (α) Geminorum (Castor) 276, 374 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 436, 437, 443 Alpha (α) Herculis (Ras Algethi) 285, 364 Alpha (α) Horologii 419 Alpha (α) Hydrae (Alphard) 394 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 442, 443 Alpha (α) Leonis (Regulus) 253, 377 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 443 naked-eye astronomy 77 name, origin of 72 Alpha (α) Librae (Zubenelgenubi) 379 Alpha (α) Lyrae (Vega) 253, 365, 366 Hertzsprung–Russell (H–R) diagram 232 luminosity 233 in monthly sky guides 448, 454, 460, 461, 466, 467, 472, 473, 478, 479 naked-eye astronomy 77 Alpha (α) Mensae 422 Alpha (α) Microscopii 296, 403 Alpha (α) Monocerotis 393 Alpha (α) Orionis (Betelgeuse) 25, 256, 390, 392 apparent magnitude 71 classification 233, 233 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 431, 436, 497

Alpha (α) Orionis cont. naked-eye astronomy 77 Winter Triangle 436, 436, 496 Alpha (α) Pavonis 424 Alpha (α) Pegasi 386 Alpha (α) Persei (Mirphak) 232, 370, 496 Alpha (α) Persei Cluster 370, 496 Alpha (α) Piscis Austrini (Fomalhaut) 253, 404, 404 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 467, 473, 478, 479, 484, 491, 497 Alpha (α) Piscium (Alrescha) 388, 388 Alpha (α) Scorpii (Antares) 256, 381, 402 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 449, 454, 460, 461, 461 Alpha (α) Serpentis (Unukalhai) 380 Alpha (α) Tauri (Aldebaran) 256, 372 classification 233 Hertzsprung–Russell (H–R) diagram 232 and Hyades 290 in monthly sky guides 431, 491 naked-eye astronomy 77 Alpha (α) Triangulum Australis 414 Alpha (α) Ursae Majoris (Dubhe) 72, 360 Hertzsprung–Russell (H–R) diagram 232 Alpha (α) Ursae Minoris (Polaris) 278–79, 354, 354, 360 circumpolar stars 348 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 448, 454 naked-eye astronomy 77, 77 Alpha (α) Virginis (Spica) 378 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 442, 443, 448, 449, 454, 455, 460, 461, 466, 467 naked-eye astronomy 77 Alpha (α) Vulpeculae 384 alphabet, Greek 7, 349 Alphard (Alpha (α) Hydrae) 394 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 442, 443 Alpheca (Alpha (α) Corona Borealis) 460 Alpheratz (Alpha (α) Andromedae) 368, 386 Alphonsus Crater (Moon) 145 Alrescha (Alpha (α) Piscium) 388, 388

INDEX Aoede 181 aperture binoculars 80 telescopes 83, 83, 84, 85 Aphrodite 388 Aphrodite Terra (Venus) 117, 121 Apollinaris Patera (Mars) 160 Apollo asteroids 170, 170 Apollo missions 138, 141, 142–43, 144, 146, 253 apparent magnitude 71, 233 April sky guide 448–53 Apus (the Bird of Paradise) 423 Delta (δ) Apodis 423 Theta (θ) Apodis 423 Aquarius (the Water Carrier) 387 Eta (η) Aquarii 387, 455 Gamma (γ) Aquarii 387 Helix Nebula 257, 387, 387, 479 in monthly sky guides 485, 485, 491 Pi (π) Aquarii 387 Saturn Nebula 255, 387, 387, 479 Zeta (ζ) Aquarii 387 Aquila (the Eagle) 383 Alshain (Beta (β) Aquilae) 383 see also Altair (Alpha (α) Aquilae) Eta (η) Aquilae 286, 383 Lambda (λ) Aquilae 383 sky guide 472 Tarazed (Gamma (γ) Aquilae) 383, 383 15 Aquilae 383 57 Aquilae 383 Aquila Rift, Milky Way 229 Ara (the Altar) 415 Stingray Nebula 264 Arabs constellations 346 mythology 279 star names 346 Arago ring (Neptune) 205 Aratus of Soli 346 Arche 180 Archer see Sagittarius Arcturus (Alpha (α) Boötis) 360, 363 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 442, 448, 449, 454, 455, 460, 461, 466, 467, 472 naked-eye astronomy 77 Arecibo radio telescope 57, 91 Arenal volcano (Earth) 131 Argo Navis 409, 410, 411, 436 argon Earth’s atmosphere 126 Moon’s atmosphere 137 Argonauts 410 Argyre Planitia (Mars) 165 Ariadne 379 Ariel 201, 203 Aries (the Ram) 371 Alpha (α) Arietis 371 Beta (β) Arietis 371 Gamma (γ) Arietis 371, 371 Lambda (λ) Arietis 371 Pi (π) Arietis 371 sky guide 496 Arion 385 Aristarchus Crater (Moon) 144 Aristotle 63, 63

Arkangelsky crater 168–69 arms, spiral galaxies 303 Armstrong, Neil 144 Arp, Halton 308 Arp 157 (NGC 520) 308 Arp 272 (NGC 6050/IC 1179) 308 Arp-Madore 1 (AM1) 419 Arrow see Sagitta Arsia Mons (Mars) 156 Artemis Chasma (Venus) 121 Artemis Corona (Venus) 121 Asclepius 381, 381 Ascraeus Mons (Mars) 156 Asellus Australis 375 Asellus Borealis 375 asterisms 72 asteroids 25, 170–77 Annefrank 172 asteroid belt 172 Ceres 175 collisions 171, 171 Eros 13, 170, 172, 176–77 formation of 235 formation of Moon 137, 137 Gaspra 172 Ida 100, 170, 173 impact craters on Moon 139 Itokawa 175 Lutetia 172 Mathilde 172 orbits 102, 103, 170, 170–71 Steins 172 structure 170 Toutatis 172 Vesta 174 Asterope 291, 373 astrology 64, 67 astrometric binaries 274 astronauts, weightlessness 38 astronomical observatories 90–95 on Earth 90–91 space 94–95 radio astronomy 91, 91 see also individual named observatories, telescopes astrophotography 88–89 Atacama Large Millimeter Array 92–93 Aten asteroids 170 Atlantic Ocean (Earth) 130 Atlas 190, 291, 372 atlases, star 347 atmosphere (Earth) 126, 126 aurorae 74, 74–75, 107 ice haloes 74, 74 moving lights and flashes 75, 75 noctilucent clouds 75, 75, 460 zodiacal light 75, 75 atmospheres formation of 235 Jupiter 180, 180 Mars 151, 151 Mercury 111, 111 Moon 137, 137 Neptune 204, 204, 205, 205 old stars 236 Pluto 209 Saturn 189, 189 Sun 107, 107 Titan 196 Uranus 201, 201 Venus 115, 115 atomic bomb 41 atomic number, chemical elements 29

atoms 24, 28, 28–29 after Big Bang 54 Big Bang 48 in chemical compounds 29, 29 of chemical elements 29 emergence of matter 50, 51 forces 30, 30 ionization 28 in molecules 29 nuclear fission and fusion 31, 31 AU Microscopii 296 August sky guide 472–77 Augusta family 172 Auriga (the Charioteer) 359, 430, 436, 437, 442, 496, 497 AB Aurigae 235 AE Aurigae 359, 359, 408 Almaaz (Epsilon (ε) Aurigae) 281, 283, 283, 359 see also Capella (Alpha (α) Aurigae) Zeta (ζ) Aurigae 359 Aurora Australis 74, 74 Aurora Borealis 74, 74–75 aurorae Earth 74, 74–75, 107 Jupiter 179, 179 Saturn 189 Autonoe 181 autumn equinox 65, 65, 124 azimuth/altazimuth mountings, telescopes 83 Azophi see al-Sufi

B

b Puppis 409 B stars classification 233 Regor (Gamma (γ) Velorum) 253 Wolf–Rayet stars 255 Babylonians, constellations 346 Bach Crater (Mercury) 113 bacteria 56, 57, 127 Baghdad Sulcus 194 Baily, Francis 376 Baily’s Beads 67 Balch, Emily 122 Balch Crater (Venus) 122 barium, formation of 55 Barlow lens 85 Barnard, Edward 182, 260 Barnard 33 (Horsehead Nebula) 240, 241, 391, 391 Barnard 68 24 Barnard’s Galaxy (NGC 6822) 328 Barnard’s Merope Nebula 291 Barnard’s Star 70, 232, 381 barred spiral galaxies 26, 302 NGC 1530 26 NGC 6782 318 baryons 31 Bayer, Johann 72, 347, 349 Bayeux Tapestry 216 Be stars 285 Beardmore Glacier (Earth) 135 Bebhionn 191 Becrux (Beta (β) Crucis) 412 Beehive Cluster (M44) 290, 375, 375 in monthly sky guides 436, 437, 442

Beethoven region (Mercury) 113 Belinda 201 Bellatrix (Gamma (γ) Orionis) 71 Bellerophon 386 Berenice’s Hair see Coma Berenices Bergelmir 191 Bessel, Friedrich 252 Bestia 191 Beta (β) Aquilae (Alshain) 383 Beta (β) Arietis 371 Beta (β) Camelopardalis 358 Beta (β) Canum Venaticorum 362 Beta (β) Capricorni 403 Beta (β) Centauri (Hadar) 252, 398 apparent magnitude 71 in monthly sky guides 443, 448, 449, 455, 455, 467, 473, 479 Beta (β) Corvi 397 Beta (β) Crucis (Becrux) 412 Beta (β) Cygni (Albireo) 366, 366, 472 Beta (β) Delphini (Rotanev) 385 Beta (β) Doradus 421 Beta (β) Geminorum (Pollux) 374 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 436, 437, 427 Beta (β) Gruis 417 Beta (β) Leonis (Denebola) 72 Beta (β) Leonis Minoris 376 Beta (β) Librae (Zubeneschamali) 379 Beta (β) Lyrae (Sheliak) 281, 365 Beta (β) Lyrae stars 281 Beta (β) Monocerotis 281, 393 Beta (β) Orionis (Rigel) 281, 390 classification 233, 233 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 431 Beta (β) Pegasi 386 Beta (β) Persei (Algol) 276, 370, 370, 496 Beta (β) Pictoris 29, 420, 420 Beta (β) Piscis Austrini 404 Beta Regio (Venus) 119 Beta (β) Sagittarii 400 Beta (β) Scorpii 402 Beta (β) Tauri (Alnath) 232, 359, 372 Beta (β) Tucanae 418 Beta (β) Ursae Majoris (Merak) 72, 77, 360 Betelgeuse (Alpha (α) Orionis) 25, 256, 390, 392 apparent magnitude 71 classification 233, 233 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 431, 436, 497 naked-eye astronomy 77 Winter Triangle 436, 436, 496 BHR 71 240 Bianca 201

I N D EX

Alshain (Beta (β) Aquilae) 383 Altair (Alpha (α) Aquilae) 252, 366, 383, 383 in monthly sky guides 461, 472, 473, 478, 479, 485 naked-eye astronomy 77 Altar see Ara altazimuth mountings, telescopes 83, 83, 84 aluminum, properties 29 aluminum-26 222 AM 0644-741 300–301 Amalthea 180, 181, 182 Amazon River (Earth) 134 American Association of Variable Star Observers 285, 287 amino acids 56 Ammavaru Volcano (Venus) 121 ammonia interstellar medium 228 Jupiter 180, 180 Neptune 204 Saturn 189, 189, 190 Uranus 200, 201 ammonium hydrosulphide, on Saturn 189 Amor asteroids 170, 170 analemma, Sun’s 64 Ananke 181 Andes (Earth) 131 Andromeda 368 Almach (Gamma (γ) Andromedae) 277, 368 Alpheratz (Alpha (α) Andromedae) 368, 386 in monthly sky guides 490, 490 Upsilon (υ) Andromedae exoplanets 298, 298, 299 Andromeda Galaxy (M31, NGC 224) 311, 312–13, 368, 368 binocular astronomy 81 Local Group 328, 328 in monthly sky guides 484, 485, 490, 491 radio waves 36 Anglo–Australian Planet Search 297 angular diameter 77 angular momentum 39 animals 127 Annefrank 172 annular eclipses 67 anorthite 223 anorthosite 111 Ant Nebula (Menzel 3) 259 Antarctica AASTO project 305 Ice-sheet 135 meteorites 135, 221 Antares (Alpha (α) Scorpii) 256, 381, 402 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 449, 454, 460, 461, 461 Antennae Galaxies (NGC 4038 and 4039) 37, 309, 317, 318, 397, 397 Anthe 191 antielectrons see positrons antimatter 31, 321, 321 antiparticles, Big Bang 48, 49, 50 antiquarks 31 Big Bang 48, 49, 50 Antlia (the Air Pump) 396 Zeta (ζ) Antliae 396

511

I N D EX

512

INDEX Big Bang 22, 48–51 aftermath of 54 cosmic microwave background radiation (CMBR) 36, 51, 54, 95, 337 distribution of galaxies 306 expanding space 44, 339 fate of Universe 58 galaxy formation 307 galaxy superclusters 338 inflation theory 48, 48 particle physics 31 recreating conditions 49 Big Chill 58, 58, 59 Big Crunch 58, 59, 59 Big Dipper 360–61 changing shape 70 in monthly sky guides 430, 436, 442, 448, 448, 449, 454, 466, 484 naked-eye astronomy 77, 77 naming stars 72 pattern 72, 72 Big Rip 58, 59 binary pulsars 274 binary stars 274 Alpha (α) Herculis (Ras Algethi) 285 Beta (β) Lyrae (Sheliak) 281 black holes 267 eclipsing binary stars 274, 274, 370 Epsilon (ε) Aurigae (Almaaz) 281 Eta (η) Geminorum (Propus) 284 Izar (Epsilon (ε) Bootis) 277 Lambda (λ) Tauri 284 M40 277 novae 282, 282 Polaris 278–79 Porrima 253 Type I supernovae 283, 283 Wolf–Rayet stars 255 Zeta (ζ) Boötis 277 15 Monocerotis 280 binocular astronomy 80–81 biosphere, Earth 127 Bird of Paradise see Apus BL Lacertae (BL Lac) 325, 369 BL Lacertae objects see blazars black dwarfs 235, 237, 266 Black Eye Galaxy (M64, NGC 4826) 314, 376, 376 black holes 24, 25, 26, 235, 267 accretion disks 267, 320 active galaxies 320, 320–21 Andromeda Galaxy 312, 312 Big Chill 59 Cygnus X-1 272 event horizon 43, 267 formation 236, 236, 237 galaxies 305, 305, 307 GRO J1655-40 272 hypernovae 55 lensing 267, 273 MACHO 96 273 matter 28 Milky Way 14, 226 radiation 36 singularity 26, 43 space-time 43 SS 433 26 stellar black holes 26, 26 supermassive black holes 26, 26, 59, 305, 305, 307 black smokers 130

blazars 320, 320 BL Lacertae (BL Lac) 325, 369 distribution 321 superluminal jets 321, 321 Blaze Star (T Coronae Borealis) 286 Blinking Planetary 367 blue jets 75, 75 blue light, photoelectric effect 34, 34 Blue Planetary 398 blue shift 35, 35 Blue Snowball (NGC 7662) 368, 368, 484 blue supergiants Eta (η) Carinae 248–49, 262 evolution 235 HDE 226868 272, 272 Sher 25 265 blue variable stars Pistol Star 265 blue-white stars Regor (Gamma (γ) Velorum) 253 Regulus (Alpha (α) Leonis) 253 blueberries, Martian 167, 167 BM Scorpii 290, 402 Bode, Johann Elert 314, 347, 360 Bode’s Galaxy (M81, NGC 3031) 314, 360, 360 Bohr, Niels 29 Bok globules 238, 238 BHR 71 240 Cone Nebula 242 Eagle Nebula 244 IC 2944 246, 246 Lagoon Nebula 243, 243 bolometric luminosity 233 bomb, atomic 41 bonds, states of matter 30 Boötes (the Herdsman) 363 see also Arcturus (Alpha (α) Boötis) Gamma (γ) Boötis 460 Izar (Epsilon (ε) Boötis) 25, 277, 363, 363, 460 Kappa (κ) Boötis 363 Mu (μ) Boötis 363 NGC 5548 323 Nu (ν) Boötis 363 Xi (ξ) Boötis 363 Zeta (ζ) Boötis 277 Bopp, Thomas 216 Borrelly, Comet 213, 213, 217 bosons 30, 30, 31 Big Bang 48 bow shock Orion Nebula 20–21 solar wind 125 Brahe, Tycho 82, 82, 272, 272 Tycho’s Supernova 272 Brahms Crater (Mercury) 113 brightness, stars 71 see also luminosity Brocchi’s Cluster 384, 384 Broglie, Louis de 35 bromine, properties 29 Brontë Crater (Mercury) 113 Bronze Age 291 brown dwarfs 25 extra-solar planets 298 formation 234 Gliese 229b 25 Bubble Nebula 290

bubble nebulae, Wolf–Rayet stars 264 Bug Nebula (NGC 6302) 260–61 Bull see Taurus Burns Cliff (Mars) 166, 166, 167 Butterfly Cluster (M6, NGC 6405) 290, 402, 402 in monthly sky guides 461, 461, 467, 473 Butterfly Nebula (Hubble 5) 255

C

C153 333 Cacciatore, Niccolò 385 Caelum (the Chisel) 405 Gamma (γ) Caeli 405 Calabash Nebula (OH231.8+4.2) 262 Calabi-Yau spaces 43 calcium, on Mercury 111 calderas, Martian volcanoes 156, 157, 160, 160 Caliban 201, 203 California Extremely Large Telescope (CELT) 37 Callirhoe 181 Callisto 25, 180, 187, 195 Callisto, in mythology 361 Caloris Basin (Mercury) 112, 112, 113 Calypso 190, 194 Camelopardalis (the Giraffe) 358 Beta (β) Camelopardalis 358 11 Camelopardalis 358 12 Camelopardalis 358 cameras, and astrophotography 88–89 Cancer (the Crab) 375 see also Beehive Cluster Delta (δ) Canceri 375, 375 Gamma (γ) Canceri 375, 375 Iota (ι) Canceri 375 in monthly sky guides 436, 442, 449 Zeta (ζ) Canceri 375 Cancer, Tropic of 65 Candor Chasma (Mars) 158, 159 Canes Venatici (the Hunting Dogs) 362 Beta (β) Canum Venaticorum 362 Cor Caroli (Alpha (α) Canum Venaticorum) 362, 362 La Superba (Gamma (γ) Canum Venaticorum) 362 see also Whirlpool Galaxy Canis Major (the Greater Dog) 392 HD 56925 264 see also Sirius A (Alpha (α) Canis Majoris); Sirius B Tau (τ) Canis Majoris 392, 392 UW Canis Majoris 392 Canis Major Dwarf 310 Canis Minor (the Little Dog) 346, 392 see also Procyon (Alpha (α) Canis Minoris) Canopus (Alpha (α) Carinae) 392, 411 Hertzsprung–Russell (H–R) diagram 232

Canopus cont. in monthly sky guides 431, 443, 449, 485, 491, 497 Canyon Diablo meteorite 222 canyons, on Mars 158–59, 158–59 Cape St.Vincent (Mars) 164 Cape Verde islands, cloud formations 128–29 Capella (Alpha (α) Aurigae) 359 in monthly sky guides 430, 431, 448, 484 Capricorn, Tropic of 65 Capricornus (the Sea Goat) 403, 478 Alpha (α) Capricorni 403 Beta (β) Capricorni 403 carbon atomic number 29 carbon cycle (CNO cycle) 250 dust 24 formation of 55 interstellar medium 228 and life 56 main-sequence stars 250 in meteorites 223 in old stars 236, 255 supergiant stars 254 Type I supernovae 283 Wolf–Rayet stars 255 carbon dioxide atomic structure 29 in comets 213, 218 interstellar medium 228 on Mars 151, 161, 163, 163 on Venus 115 carbon monoxide in comets 213 on Pluto 209 carbon stars 233, 256, 256 carbonaceous (C-type) asteroids 170 carbonaceous chondrite (stony) meteorites 170, 220 Carina (the Keel) 411 see also Canopus (Alpha (α) Carinae) Epsilon (ε) Carinae 411 Eta (η) Carinae 247, 248–49, 256, 262, 411, 411, 443, 449 Iota (ι) Carinae 411 in monthly sky guides 431, 436, 442 Sher 25 265 Theta (θ) Carinae 411, 443 Carina Nebula (NGC 3372) 24, 247, 248–49, 411, 411 in monthly sky guides 443, 449, 449 Carlyle, Thomas 345 Carme 181 Carpo 181 Cartwheel Galaxy (ESO 350-G40) 319 Caspian Sea (Earth) 135 Cassini, Giovanni, Saturn’s moons 194, 195, 197 Cassini Regio (Iapetus) 197, 197 Cassini spacecraft 196, 196, 198–99 Cassiopeia 357 Eta (η) Cassiopeiae 357 Gamma (γ) Cassiopeiae 285, 357 M52 290, 357, 357, 484

Cassiopeia cont. in monthly sky guides 430, 436, 490, 496 Phi (ϕ) Cassiopeiae 357 Rho (ρ) Cassiopeiae 357 Tycho’s Supernova 272 Cassiopeia, Queen 357, 368 Cassiopeia A (SN 1680) 55, 268, 273 Castor (Alpha (α) Geminorum) 276, 374 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 436, 437, 443 catadiotropic telescopes 82, 82, 83 catalogs active galaxies 322–25 asteroids 172–75 comets 214–19 constellations 354–425 galaxy clusters 328–35 main–sequence stars 252–53 multiple stars 276–81 nebulous objects 73 old stars 256–65 star-forming nebulae 240–47 star clusters 290–95 stellar end points 268–73 variable stars 284–87 Cat’s Eye Nebula (NGC 6543) 258, 355, 355 CCD (charge-coupled device) detectors, cameras 89, 89 cD galaxies 304, 326, 326, 327 CDM, cold dark matter 307 Celaeno 291 celestial coordinates 63 celestial cycles 64–76 celestial globes 346–47 celestial meridian 63 celestial poles 437 Celestial Police 171 celestial sphere 62–63, 346 constellations 72 mapping 348–53 motion of planets 68–69 motion of stars 70 Centaur see Centaurus Centaurs 208, 210 Centaurus (The Centaur) 398 IC 2944 246 see also Alpha (α) Centauri (Rigil Kentaurus); Hadar (Beta (β) Centauri) in monthly sky guides 431, 437, 442, 449, 454, 461 Omega Centauri 81, 288, 289, 290, 294, 398, 418, 449, 455, 461 Proxima Centauri 22, 232, 252, 398 RCW 49 247 Centaurus A (NGC 5128) 14, 322, 398 collision with spiral galaxy 318, 321, 324 in monthly sky guides 455, 461 Cepheid variable stars 286 measuring distances with 44, 313, 313 pulsation 282, 282 in Small Magellanic Cloud 311

INDEX Circlet 388, 388, 484, 485 circulation cells, Jupiter 180, 180 Circumnuclear Disk, Milky Way 229 circumstellar disks, formation of planets 235, 235, 296, 296 CL0024+1654 335 CL-2244-02 327 Claritas Fossae (Mars) 160 Classical Belt 209 objects 210 classification galaxies 302, 302 stars 233 Clementine space probe 139 Cleopatra Crater (Venus) 122 climate, Earth 124 closed universe 59, 59 clouds see also gas clouds Jupiter 180, 180, 181 lenticular clouds 75 Mars 151 see also molecular clouds Neptune 205 noctilucent clouds 75, 75, 460 Uranus 201, 201 Venus 115, 115 Clownface Nebula 374 clusters see galaxy clusters; galaxy superclusters; star clusters CMBR see cosmic microwave background radiation Coalsack Nebula 412, 412, 413 in monthly sky guides 449, 455, 455, 461 Coathanger 384, 384 COBE satellite 337 Cold Bokkeveld meteorite 223 cold dark matter, CDM 307 collapsing stars 237, 266 Collins, Peter 80, 80, 287 collisions, galaxies 239, 239, 318, 318 color force 30 colors, stars 70–71, 233 Columba (the Dove) 408 Mu (μ) Columbae 408 coma, comets 213 Coma Berenices (Berenice’s Hair) 376 Black Eye Galaxy 314, 376, 376 Gamma (γ) Comae Berenices 376 Malin 1 319 the Mice 318 Coma Cluster (Abell 1656) 326, 327, 332 Coma Star Cluster (Melotte 111) 376, 448, 454 Comas Solá, Comet 217 “comet clouds” 319 comets 25, 212–19 binocular astronomy 80 Borrelly 213, 213, 217, 218 Churyumov–Gerasimenko 217 Comas Solá 217 computerized telescopes 84, 84, 87, 87 Encke 212, 215 formation 235 Giacobini-Zinner 217 Great Comet of 1680 214 Hale–Bopp 212, 214, 216 Halley’s Comet 212, 213, 214, 216, 455

comets cont. Hartley 2 218 Hyakutake 80, 211, 212, 215, 216 Ikeya–Seki 214, 219 Ikeya–Zhang 25 Kuiper Belt 208–11 life cycles 213 Lovejoy 219 McNaught 219 meteoroids 220 Oort Cloud 208 orbits 212, 212 Shoemaker–Levy 9 181, 181, 217 Soho-6 213 structures 213, 213 Swift–Tuttle 212, 214, 220 Tempel–Tuttle 212, 220 Tempel 1 218 West 215, 219 Wild 2 172, 217, 218 Wirtanen 217 compact groups Seyfert’s Sextet 308, 329 Stephan’s Quintet 332 Compass see Pyxis Compasses see Circinus composite particles 31 compounds, chemical 29, 29 Compton Gamma Ray Observatory 37, 95 computerized telescopes 84, 84, 87, 87 Cone Nebula (NGC 2264) 242, 280, 393, 393 conjunction, planets 68, 69, 69 constellations 72, 72–73, 344–425 see also individual named constellations history 346–47 mapping the sky 348–53 zodiac 64, 65 contact binary systems 274 convection 250 convection cells red giants 254 Sun 106 convection currents Jupiter 180 plate tectonics 126 coordinates, celestial 63 Copernicus, Nicolaus 69 Copernicus Crater (Moon) 137, 139, 145 Coprates Chasma (Mars) 159 Cor Caroli (Alpha (α) Canum Venaticorum) 362, 362 Cordelia 201, 201, 202 core Earth 124, 124, 125 Jupiter 178, 178 Mars 150, 150 Mercury 111, 111 Moon 136, 136 Neptune 204, 204 Pluto 209 Saturn 188 Uranus 200, 200 Venus 114, 114 Coriolis effect 126, 126, 180 corona, Sun 10, 67, 106, 107, 107 Corona Australis (the Southern Crown) 415 Gamma (γ) Coronae Australis 415

Corona Australis cont. Kappa (κ) Coronae Australis 415 RX J1856.5-3754 268 Corona Borealis (the Northern Crown) 379, 460 Abell 2065 (Corona Borealis Cluster) 333 Alpheca (Alpha (α) Corona Borealis) 460 Nu (ν) Coronae Borealis 379 R Coronae Borealis 283, 287, 379 Sigma (σ) Coronae Borealis 379 T Coronae Borealis (Blaze Star) 286 Zeta (ζ) Coronae Borealis 379 coronal mass ejections (CMEs), Sun 106, 107, 107 Corot mission 297 Corvus (the Crow) 397 Alpha (α) Corvi 397 Antennae Galaxies 37, 317, 318, 397, 397 Beta (β) Corvi 397 Delta (δ) Corvi 397 Epsilon (ε) Corvi 397 Gamma (γ) Corvi 397 Cosmic Background Explorer 95 cosmic light horizon 23 cosmic microwave background radiation (CMBR) 36, 51, 54, 95, 337 Sunyaev–Zel’dovich effect 334, 335 cosmic rays 24, 34, 228 cosmological constant 58 cosmological red shift 35 cosmologists 22 covalent compounds 29 Crab see Cancer Crab Nebula (M1, NGC 1952) 270–71, 372, 372 Crane see Grus Crater (the Cup) 72, 397, 442 craters see impact craters; volcanoes Crescent Nebula (NGC 6888) 259 Cressida 201 CRL 2688 (Egg Nebula) 258 Crow see Corvus crust Earth 124, 124, 126, 126 Mars 150 Moon 136 Crux (the Southern Cross) 412 Acrux (Alpha (α) Crucis) 412, 455 Becrux (Beta (β) Crucis) 412 Gacrux (Gamma (γ) Crucis) 232, 412 see also Jewel Box (Kappa (κ) Crucis) in monthly sky guides 437, 443, 448, 449, 454, 455, 461 Mu (μ) Crucis 412 naked-eye astronomy 77 Pointers 252 Culann Patera (Io) 184 Cunitz Crater (Venus) 122 Cup see Crater Cupid 201

cycles, celestial 64–67 Cygnus (the Swan) 366–67 Albireo (Beta (β) Cygni) 274, 277, 366, 366, 472 Crescent Nebula 259 Cygnus A (3C 405) 324, 367 Cygnus X-1 272, 367 see also Deneb (Alpha (α) Cygni) DR 6 243 DR 21 246 in monthly sky guides 472, 490, 496 Nova Cygni 1992 287 Omicron (ο) Cygni 366 TT Cygni 256 56 Cygni 72 61 Cygni 232, 252, 367 Cygnus Loop (NGC 6960/95) 228, 269 Cygnus Rift 367, 472 Cygnus Star Cloud 272 Cyllene 181

D

Dactyl 173 Daedalia Planum (Mars) 160 Dali Chasma (Venus) 121 Danilova Crater (Venus) 123 Dante Alighieri 184 Daphnis 191 dark ages 54, 337 dark energy 27, 54, 58–59, 58, 339 dark galaxies 326 dark matter 27, 28, 54 dwarf elliptical galaxies 304 galaxies 307 galaxy superclusters 337, 338 gravitational lensing 335 Milky Way 229 dark nebulae 24, 228, 240 Barnard 68 24 BHR 71 240 Cone Nebula 242 Horsehead Nebula 240 Dawn spacecraft 174, 175 days, measuring 66, 66 December sky guide 496–501 declination 63, 63, 77, 87 Deep Impact probe 218 Deep Space 1 mission 217 Degas Crater (Mercury) 113 degrees of angle 77 Deimos 153, 153 Delphinus (the Dolphin) 385 Delta (δ) Delphini 385 Gamma (γ) Delphini 385 Rotaney (Beta (β) Delphini) 385 Sualocin (Alpha (α) Delphini) 385 Delta (δ) Apodis 423 Delta Aquarid meteor shower 467 Delta (δ) Canceri 375, 375 Delta (δ) Cephei 286, 356, 356, 478 Delta (δ) Chamaeleontis 423 Delta (δ) Corvi 397 Delta (δ) Delphini 385 Delta (δ) Gruis 417, 417 Delta (δ) Librae 379 Delta (δ) Lyrae 365 Delta (δ) Octantis 425 Delta (δ) Orionis 390

I ND E X

Cepheus 356 Delta (δ) Cephei 286, 356, 356, 478 Epsilon (ε) Cepheus 356 IC 1396 243 Lambda (λ) Cepheus 356 Mu (μ) Cephei (Garnet Star) 232, 243, 243, 254, 287, 356, 356 Zeta (ζ) Cepheus 356 Ceres 170, 171, 175 CERN (European Center for Nuclear Research) 49, 52–53 Cerro Tololo Inter-American Observatory 262 CETI (communication with extraterrestrial intelligence) 57 Cetus (the Sea Monster) 389 Gamma (γ) Ceti 389 Menkar (Alpha (α) Ceti) 389 Mira (Omicron (ο) Ceti) 285, 389, 490, 491, 491 in monthly sky guides 485, 490, 491, 496 Tau (τ) Ceti 232, 389 ZZ Ceti 232 Chaffee, Roger 253 Chaldene 181 Chamaeleon (the Chameleon) 423 Delta (δ) Chamaeleontis 423 Chameleon see Chamaeleon Chandra X-ray Observatory 37, 95, 230, 272 Chandrasekhar limit 266 Chandrayaan-1 mission 141, 149 Chang’e mission 141 charge-coupled device (CCD) detectors, cameras 89, 89 charged particles aurorae 74, 107 ions 28 Jupiter 179 magnetic fields 251 pulsars 267 solar wind 107, 125 Sun 106 Charioteer see Auriga Charitum Montes (Mars) 165 Charles I, King of England 362 Charon 209, 209 charts, star 347 Chasma Boreale (Mars) 153 chasmata, on Mars 158–59 chemical compounds 29, 29 chemical elements see elements Chéseaux, Philippe Loys de 244 China, and Polaris 279 Chiron 208, 208, 210 in mythology 398 Chisel see Caelum chondrites 222, 223 chondrules 222, 223, 223 Christmas Tree Cluster 242 Christy, James 209 chromosphere (Sun) 107, 107 Chryse Planitia (Mars) 158 Churyumov, Klim 217 Churyumov–Gerasimenko, Comet 217 Cigar Galaxy (M82, NGC 3034) 73, 305, 314, 360 Circinus (the Compasses) 413 Alpha (α) Circini 413 Circinus Galaxy (ESO 97-G13) 322

513

INDEX

514

INDEX Delta (δ) Scorpii 402 Delta (δ) Scuti 382 Delta (δ) Serpentis 380 Delta (δ) Telescopii 416 Delta (δ) Ursae Majoris 360 Delta (δ) Velorum 410 Deneb (Alpha (α) Cygni) 366 Hertzsprung–Russell (H–R) diagram 232 luminosity 233 in monthly sky guides 460, 467, 472, 473, 478, 479 naked-eye astronomy 77 Denebola (Beta (β) Leonis) 72 density waves formation of stars 234 spiral galaxies 227, 239, 303 Desdemona 201 deserts, on Earth 127, 127 Despina 205 deuterium 51 Devana Chasma (Venus) 119 Dido Crater (Dione) 195 differential rotation, spiral galaxies 302 digiscoping 88, 88 digital astrophotography 88, 88 stacking 89 dimensions Calabi-Yau spaces 43 space-time 41 Dione 190, 191, 192, 195 direct imaging, exoplanets 297 Discovery Rupes (Mercury) 113 disrupted spiral galaxies Antennae Galaxies 317 Cartwheel Galaxy 319 ESO 510-G13 318 the Mice 318 distance apparent magnitude 233 expanding space 44–45, 339 mapping the Universe 339 naked-eye astronomy 77, 77 parallax shift 70, 70 pulsating variable stars 282 size of Universe 22–23 DIXI mission 218 DNA 127 Dobsonian telescope mount 83, 83, 84 Dolphin see Delphinus Domovoy Crater (Ariel) 203 Doppler effect 35 Doppler spectroscopy 297, 297 Dorado (the Goldfish) 421 Beta (β) Doradus 421 see also Large Magellanic Cloud R Doradus 421 see also Tarantula Nebula (30 Doradus) double binary stars 274 Double Cluster 370, 370, 496 double-slit test 34 double stars see binary stars Dove see Columba DR 6 243 DR 21 246 Draco (the Dragon) 355, 460, 466 Abell 2218 334–35 Cat’s Eye Nebula 258, 355, 355 Etamin (Gamma (γ) Draconis) 355

Draco cont. Mu (μ) Draconis 355 Nu (ν) Draconis 355 Omicron (ο) Draconis 355 Psi (ψ) Draconis 355 Spindle Galaxy 317 16 Draconis 355 17 Draconis 355 39 Draconis 355 40 Draconis 355 41 Draconis 355 Dragon see Draco Drake, Frank 57 Draper, Henry 241 Dreyer, J.L.E. 239 Dubhe (Alpha (α) Ursae Majoris) 72, 360 Hertzsprung–Russell (H–R) diagram 232 Duck Bay (Mars) 164 Dumbbell Nebula (M27) 89, 257, 384, 384, 472, 473 Dunlop, James 260 Dürer, Albrecht 347 dust interstellar medium 24, 228 storms on Mars 159 zodiacal light 75, 75 dwarf elliptical galaxies 16–17, 304, 304, 310 Canis Major Dwarf 310 galaxy clusters 326, 326 SagDEG 310 dwarf planets see Kuiper Belt Objects dwarf stars black dwarfs 235, 237, 266 brown dwarfs 25, 25, 234, 298 red dwarfs 25, 25, 235 see also white dwarfs Dysnomia 210, 210

E

e Puppis 409 Eagle see Aquila Eagle Crater (Mars) 163 Eagle Nebula (IC 4703) 238, 244–45, 380, 380, 467 Earth 8, 25, 124–35, 142–43 asteroids 170 atmosphere and weather 126, 126 aurorae 74, 107 axis of rotation 64, 64 celestial sphere 62–63 climate 124 cloud vorticies 128–29 Earthrise 142–43 eclipses 67 features formed by water 134–35 life 56–57, 127, 127 lights in the sky 74–75 magnetic field 125, 125 meteorite craters 221, 221, 222–23 meteorites 220 the Moon 136, 137, 138, 138 orbit and spin 102, 124, 124 plate tectonics 126, 126 seasons 65, 65, 124 size 22 structure 124, 124

Earth cont. surface features 127 tectonic features 126, 130–33 earthquakes Mercury 112 meteorite impacts 221 eclipses 67 eclipsing binary stars 274, 274, 370 Alpha (α) Herculis (Ras Algethi) 285 Eta (η) Geminorum (Propus) 284 Lambda (λ) Tauri 284 ecliptic 64, 65, 124 Eddington, Sir Arthur 251 Edgeworth, Kenneth 208 Edgeworth–Kuiper Belt 208 Egg Nebula (CRL 2688) 258 Egypt, constellations 346 Eight-Burst Nebula (NGC 3132) 254–55, 410, 443 Einstein, Albert 31, 40 cosmological constant 58 energy and mass 41 general theory of relativity 42–43, 51 mass and energy 58 Mercury’s orbit 110 principle of equivalence 42, 42 special theory of relativity 40–41 Eistla Regio (Venus) 119 Elara 180 Electra, in mythology 373 electromagnetic (EM) force 30, 30, 49 electromagnetic (EM) radiation 34–37 “false color” images 37, 37 observing 34–37 Sun 104 electron degeneracy pressure, white dwarfs 266 electrons 28, 28–29 Big Bang 49, 50, 50–51 Big Chill 59 chemical elements 29 forces 30, 30 molecules 29 photoelectric effect 34, 34 plasma 30 synchrotron mechanism 320 electroweak era 48–49 electroweak force 49 elements 29 formation of 55, 266, 266 high-mass stars 236 planet formation 235 spectroscopy 35, 35 star formation 234 supergiant stars 254 Elephant’s Trunk Nebula 243, 243 ellipses, orbits 39, 39 elliptical galaxies 26, 304 classification 302, 302 distribution 306 galaxy clusters 326, 327 M60 317 SagDEG 310 ELODIE 297 Eltanin 355 Elysium Planitia (Mars) 162 emission nebulae 24, 35, 228, 240 Carina Nebula 247, 248–49

emission nebulae cont. DR 6 243 DR 21 246 Eagle Nebula 244–45 IC 1396 243 IC 2944 246 Lagoon Nebula 243 M43 241, 391 NGC 604 311, 311 NGC 2359 264 Omega Nebula 240, 400, 401 Orion Nebula 241 RCW 49 247 Trifid Nebula 246 emission spectrum 35, 35, 233 planetary nebulae 255 Wolf–Rayet stars 255 Enceladus 190, 191, 194 Encke, Comet 212, 215 Encke, Johann 215 Encke gap, Saturn’s rings 191 Encounter 2001 message 57 end points, stellar 266–73 Endurance Crater (Mars) 166–67 Energetic Gamma (γ) Ray Experiment Telescope (EGRET) 37 energy atomic bomb 41 atoms 28 Big Bang 48 convection 250 dark energy 27, 54, 58–59, 58, 339 electromagnetic (EM) radiation 34, 34 fate of Universe 58–59 ionization 28 luminosity 233 main-sequence stars 250 mass 41, 41 nuclear fission and fusion 31, 31 photons 34 protostars 239 radiation 250 rotation 39 Saturn 189 stars 232 states of matter 30 strong nuclear force 30 Sun 104 supernovae 266 Enif (Epsilon (ε) Pegasi) 386, 478 Enki Catena (Ganymede) 213 Ensisheim meteorite 222 Eos Chasma (Mars) 159 Epimetheus 190, 192 EPOCh mission 218 EPOXI mission 218 Epsilon (ε) Aurigae (Almaaz) 281, 283, 283, 359 Epsilon (ε) Bootis (Izar) 25, 277, 363, 363, 460 Epsilon (ε) Carinae 411 Epsilon (ε) Cepheus 356 Epsilon (ε) Corvi 397 Epsilon (ε) Herculis 364 Epsilon (ε) Hydrae 394 Epsilon (ε) Indi 416 Epsilon (ε) Lupi 399 Epsilon (ε) Lyrae 276, 365 Epsilon (ε) Normae 414 Epsilon (ε) Orionis (Alnilam) 232 Epsilon (ε) Pegasi (Enif) 386, 478

Epsilon (ε) Sagittarii 400 Epsilon (ε) Sculptoris 404 Epsilon (ε) Ursae Majoris (Alioth) 72, 360 Epsilon (ε) Volantis 422 equator, celestial sphere 62, 63 equatorial mountings, telescopes 83, 83, 84, 86–87 equatorial sky charts 350–53 equinoxes 65, 65, 124 Pisces 388 precession 371 sky guide 442 Equuleus (the Foal) 385 Gamma (γ) Equulei 385 1 Equulei 385 Erichthonius 359 Eridanus (the River) 406, 485, 497 see also Achernar (Alpha (α) Eridani) Omicron (ο) Eridani 276, 406, 406 Theta (θ) Eridani 406 32 Eridani 406 40 Eridani B 232 Erie, Lake (Earth) 134 Erinome 181 Eris 210, 210 Eros 13, 170, 172, 176–77 mythology 388 erosion Mars 164, 164 Venus 117 Erriapus 191 eruptive variable stars 262 U Geminorum 284 ESA see European Space Agency Eskimo Nebula (NGC 2392) 374, 374, 259 ESO 97-G13 (Circinus Galaxy) 322 ESO 350-G40 (Cartwheel Galaxy) 319 ESO 510-G13 318 Eta Aquarid meteor shower 387, 454, 455 Eta (η) Aquarii 387, 455 Eta (η) Aquilae 286, 383 Eta (η) Carina Nebula see Carina Nebula Eta (η) Carinae 247, 248–49, 256, 262, 411, 411, 443, 449 Eta (η) Cassiopeiae 357 Eta (η) Geminorum (Propus) 284, 374 Eta (η) Herculis 364 Eta (η) Lupi 399 Eta (η) Piscium 388 Eta (η) Tauri (Alcyone) 277, 291, 372 Eta (η) Ursae Majoris (Alkaid) 72, 360 Eta (η) Ursae Minoris 354 Etamin (Gamma (γ) Draconis) 355 ethane Jupiter 180 Saturn 189 “ether” 40 Euanthe 181 Eudoxus 346 Eukelade 180, 181 Euporie 181 Europa 25, 180, 182–82 possibility of life 57

INDEX European Center for Nuclear Research (CERN) 49, 32–33 European Space Agency (ESA) Giotto mission 216 Hipparcos satellite 70, 70 Rosetta mission 172, 217, 218 Eurydome 181 evaporating gaseous globules (EGGs) 238, 244 event horizon, black holes 43, 267 Everest, Mount (Earth) 132, 132 evolution galaxies 306–309 galaxy clusters 327 life 127 multiple stars 274, 274 star clusters 289 stars 234–37 exoplanets see extra-solar planets exotic particles 31, 48 expanding space 44–45, 58, 335, 338–39, 339 Explorer 1 satellite 125 extra-solar planets 296–99 extraterrestrial life 57 Extreme Ultraviolet Explorer 37 extremophile organisms 57 eyepieces, telescopes 82, 83, 85, 85 eyes, adjusting to dark 76

F

G

G stars 233 Gacrux (Gamma (γ) Crucis) 232, 412 Gaea (Amalthea) 182 Gaia Astronometry Satellite 94 Galactic Center, Milky Way 240 Galatea 205, 205 galaxies 14–15, 24, 26, 302–39 see also elliptical galaxies, spiral galaxies, individual named galaxies active galaxies 306–309 barred spiral 26, 26, 302, 318 Big Chill 59 black holes 26, 305, 305, 307 catalogs 73 classification 302, 302 clusters 16–17, 23, 24 collisions 239, 239, 309, 318, 318 dark matter 307, 337 density waves 239 distribution 306 earliest 335 evolution 306–307 expanding space 44, 44, 339 formation 55, 55, 307 giant elliptical galaxies 310

galaxies cont. gravitational lensing 306, 334–35 interstellar medium 228 irregular galaxies 26, 305 lenticular galaxies 26, 304 merging 327 radiation 36 red shift 35, 35 rotation 39 Seyfert galaxies 308, 315, 320, 320 star formation 239, 239 superclusters 16, 23, 336–39 tidal forces 309 types of 302–305 wavelengths 305 galaxy clusters 16–17, 27, 326–35 Abell 1689 333 Abell 2065 (Corona Borealis Cluster) 333 Abell 2125 333 Abell 2218 334–35 Coma Cluster 332 evolution 327 Fornax Cluster 329 gravity bending light 43 Hercules Cluster 333 Hickson Compact Group 27 Hydra Cluster 332 Local Group 27, 326, 326, 328, 336 radiation 36 Sculptor Group 329 Seyfert’s Sextet 308, 329 Stephan’s Quintet 332 Virgo Cluster 329 X-rays 329, 329 galaxy superclusters 16, 23, 24, 27, 336–39 filaments 337, 337, 338–39 formation 54, 54, 337 sheets 338 voids 338–39 Galilean moons (Jupiter) 25, 180, 182–87 Galileo Galilei Galilean moons 25, 182–83 mapping the Moon 82, 139, 139 Saturn’s rings 191 study of gravity 38 Galileo space probe 173, 182, 183, 183 Galle ring (Neptune) 205, 205 Gamma (γ) Andromedae (Almach) 277, 368 Gamma (γ) Aquarii 387 Gamma (γ) Aquilae (Tarazed) 383, 383 Gamma (γ) Arietis 371, 371 Gamma (γ) Boötis 460 Gamma (γ) Caeli 405 Gamma (γ) Canceri 375, 375 Gamma (γ) Canum Venaticorum (La Superba) 362 Gamma (γ) Cassiopeiae 285, 357 Gamma (γ) Ceti 389 Gamma (γ) Comae Berenices 376 Gamma (γ) Coronae Australis 415 Gamma (γ) Corvi 397 Gamma (γ) Crucis (Gacrux) 232, 412 Gamma (γ) Draconis (Etamin) 355

Gamma (γ) Equulei 385 Gamma (γ) Leonis (Algieba) 377, 377 Gamma (γ) Leporis 407 Gamma (γ) Lyrae 365 Gamma (γ) Orionis (Bellatrix) 71 Gamma (γ) Pegasi 386 Gamma (γ) Piscis Austrini 404 gamma rays 31, 34 Geminga Pulsar 268 main-sequence stars 250 Milky Way 227, 321 observatories 37, 37 Gamma (γ) Ursae Majoris (Phad) 72, 360 Gamma (γ) Ursae Minoris 354 Gamma (γ) Velorum (Regor) 233, 253, 410 Gamma (γ) Virginis (Porrima) 253, 378 Gamma (γ) Volantis 422 Gamma-1 (γ1) Normae 414 Gamma-2 (γ2) Normae 414 Gamow, George 50, 51 Ganymede 25, 180, 186, 196 impact craters 213 Ganymede, in mythology 387 Gaposchkin, Sergei 233 Garnet Star (Mu (μ) Cephei) 232, 243, 243, 254, 287, 356, 356 gas clouds 24, 28 Eta (η) Carinae Nebula 24, 248–49 formation of Solar System 100–101 galaxy collisions 308 gas-giant planets 25, 103 extra-solar planets 298, 298 formation of Solar System 101 Jupiter 178–87 Neptune 204–207 Saturn 188–99 Uranus 200–203 gases interstellar medium 228 molecules 24 novae 282 spectroscopy 35 states of matter 30 Sunyaev–Zel’dovich effect 334 Gaspra 172 gauge bosons 31 gegenschein 75, 75 Geminga Pulsar (SN 437) 268 Gemini (the Twins) 374 see also Castor (Alpha (α) Geminorum) Eskimo Nebula 259 Eta (η) Geminorum (Propus) 284, 374 Geminga Pulsar 268 in monthly sky guides 436, 442, 448, 454, 490, 496, 497 see also Pollux (Beta (β) Geminorum) U Geminorum 284 Zeta (ζ) Geminorum (Mekbuda) 286, 374 Gemini spectrograph 339 Geminid meteor shower 374, 496, 496 general theory of relativity 42–43, 51 genes 56 geometry, space-time curvature 59

Gerasimenko, Svetlana 217 Gertrude Crater (Titania) 203 Ghost of Jupiter 394, 394 Ghost Nebula (NGC 1977) 89, 391 Ghost Stream 308 Giacobini–Zinner, Comet 217 giant elliptical galaxies 304, 304, 310 galaxy clusters 326, 327 giant stars 25 Aldebaran 256 classification 233 evolution 235, 236 Hertzsprung–Russell (H–R) diagram 232, 232, 255 multiple stars 274 novae 282 planetary nebulae 255 red giants 25, 254 star life cycles 234–37, 236 see also supergiants TT Cygni 256 Type I supernovae 283, 283 Giotto mission 216 Giraffe see Camelopardalis glacial lakes, on Earth 132 glaciers, on Earth 135 glass impactites 221 volcanic glass 147, 147 Glatton meteorite 222 Gliese 229 25 Gliese 229b 25 Gliese 436b 299 Global Microlensing Alert Network 273 Global Positioning System (GPS) 41, 87 global warming, Earth 135 globes, celestial 346–47 globular clusters 289, 289, 290 M4 294 M12 295 M14 295 M15 295 M68 295 M107 295 Milky Way 229, 229 NGC 3201 294 NGC 4833 295 Omega Centauri 294 47 Tucanae 294 gluons 28, 29, 31 Big Bang 48, 50, 50 forces 30 recreating Big Bang 49 Golden Fleece 371 Goldfish see Dorado Gomez, Arturo 262 Gomez’s Hamburger Nebula (IRAS 18059-3211) 262 Gossamer Ring (Jupiter) 182 go-to telescopes 84, 84. 87, 87 GPS (Global Positioning System) 41, 87 Gran Telescopio Canarias 90, 91 Grand Canyon (Earth) 134, 158 Grand Unified Theory era 48 granulation, Sun 106 gravitational lensing black holes and 267, 273 extra–solar planets 297 galaxies 306 galaxy clusters 327, 327, 334–35 gravitational waves, binary pulsars 274

I N D EX

f number 83 F stars 233 Fabricius, David 285 faculae, Sun 85, 106, 108–109 false color images, electromagnetic radiation 37, 37 False Cross 410, 411 in monthly sky guides 437, 443 naked-eye astronomy 77 Family Mountain (Moon) 146 Farbauti 191 February sky guide 436–41 Fenrir 191 Ferdinand 201 Fermi Gamma-ray Space Telescope 37, 95 fermions 31 field equations 43 field galaxies 326 field of view 81, 83 filaments 54, 337, 337, 338–39 filters 85, 85 finders, finderscopes 84, 84, 87 fireballs 75, 220 Fishes see Pisces Fish’s Mouth 241 Flaming Star Nebula 359 star atlas 72, 347, 347 flare stars 252 flares, solar 10, 98–99, 106, 250 flat universe 58, 59, 59 flocculent spiral galaxies 303, 303, 311 Florida Keys 9 Fly see Musca Flying Fish see Volans flying saucers 75, 75

Foal see Equuleus focal length and ratio 83 focusing binoculars 81 Fomalhaut (Alpha (α) Piscis Austrini) 253, 404, 404 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 467, 473, 478, 479, 484, 491, 497 force-carrier particles 30, 30, 31, 48 forces Big Bang 48 electromagnetic (EM) force 30, 30 gravity 30, 38–39 string theory 31 strong nuclear force 30, 30 weak nuclear force 30, 30 forests, on Earth 127, 127 fork telescope mount 83, 87 Fornax (the Furnace) 405 Alpha (α) Fornacis 405 Fornax A 405 Fornax Cluster (Abell S 373) 329, 405, 405 Fornax dwarf galaxy 328 Fornjot 191 Fortuna Tessera (Venus) 118 Fox see Vulpecula Francisco 201 Frank, Anne 172 Fraunhofer, Joseph von 107 Fraunhofer lines 107 free fall 38, 39 Fried Egg Galaxy (NGC 7742) 323 Fuji, Mount (Earth) 131 fundamental particles 31, 48, 50 fundamental strong nuclear force 30, 30 fungi 127 Furnace see Fornax

515

516

INDEX gravitons 31, 48 gravity 24, 30, 38–39 Big Bang 48 Big Crunch 58, 59, 59 black holes 26, 267 development of structures 54, 54 expanding space 44, 58, 339 galaxy clusters 27 galaxy superclusters 336–39 globular clusters 289 light 42, 42, 43 matter 28 Moon 137, 138, 138 multiple stars 274, 274 orbits 39, 39 particle physics 31 planet formation 235 precession 64 Principle of Equivalence 42, 42 protostars 239 quantum gravity 43 red giants 254 Solar System 100 space-time 42–43, 42–43 star formation 234, 234, 238, 239 stars 232, 232 Great Attractor 336, 336 Great Bear see Ursa Major Great Comet of 1680 214 Great Cold Spot 337 Great Dark Spot (Neptune) 205, 205 Great Lakes (Earth) 134 Great Red Spot (Jupiter) 12–13, 181, 181 Great Rift Valley (Earth) 130, 160 Great White Spots (Saturn) 190 Greater Dog see Canis Major Greece, constellations 346 Greek alphabet, Bayer’s system 72, 347, 349 Green Bank Radio Telescope 91 greenhouse effect, on Venus 115 Greip 191 GRO J1655-40 272 Grus (the Crane) 417, 479 Beta (β) Gruis 417 Delta (δ) Gruis 417, 417 Mu (μ) Gruis 417, 417 Guardians of the Pole 354 Guardians of the Sky 256 Gula Mons (Venus) 119 GUM 29 247 Gum Nebula see Vela Supernova

I N D EX

H

H1504+65 266 h3752 407 habitable zone, exoplanet 299 Hadar (Beta (β) Centauri) 252, 398 apparent magnitude 71 in monthly sky guides 443, 448, 449, 455, 455, 467, 473, 479 Hadley, John 425 Hadriaca Patera (Mars) 163 Hadron Era 50 hadrons 31, 50 Hahn, Friedrich von 257

Hale, Alan 216 Hale–Bopp, Comet 212, 214, 216 Hale Crater (Mars) 164 Hale Telescope 90, 90 Halimede 205, 206 Hall, Asaph 153 Halley, Edmond 73, 262 Halley’s Comet 214, 216 Eta Aquarid meteor shower 455 orbit 212 tail 213 halo stars 229 haloes ice 74, 74 Milky Way 229, 273 Hamlet Crater (Oberon) 203, 203 Harch, Ann 173 Harding, Karl Ludwig 257 Hare see Lepus Harold II, King of England 216 Harpalyke 181 HARPS 297 Hartley, Malcolm 218 Hartley 2, Comet 218 Harvest Moon 478 Hati 191 Haumea 210 Hawking, Stephen 21 Hayabusa mission 175 Hazard, Cyril 325 HD 23608 277 HD 44179 (Red Rectangle Nebula) 258 HD 48915 B see Sirius B HD 53143 208 HD 56925 264 HD 62166 (NGC 2440 nucleus) 268 HD 107146 296 HD 189733b 298 HD 206267 243 HD 209558b 298 HD 226868 272, 272 heat 34 protostars 239 states of matter 30 see also temperature Hegemone 181 Helen of Troy 374 Helene 190, 195 Helike 181 Helios space probe 105, 105 helium 24 Big Bang 50, 50–51, 54 atomic number 29 burning in old stars 236, 236, 255 carbon stars 256 first stars 55 helium flash 255 Jupiter 178, 178, 180, 180 main-sequence stars 250, 251 Mercury 111, 111 Moon’s atmosphere 137 nebulae 238 Neptune 204, 205 nuclear fusion 31, 31 red giants 254 Saturn 188 star formation 234 stars 232, 234 Sun 104 supergiants 254 on Uranus 201 Wolf–Rayet stars 255

Helix Nebula (NGC 7293) 257, 387, 387, 479 Hellas Basin (Mars) 152 Hellas Planitia (Mars) 165 hematite, on Mars 163, 167 Hen-1357 (Stingray Nebula) 264 Herbig Haro objects 242 Hercules 72, 364 Epsilon (ε) Herculis 364 Eta (η) Herculis 364 Kappa (κ) Herculis 364 Keystone 364, 460, 466 in monthly sky guides 466, 472 mythology 227, 355, 355, 375, 377, 394 Pi (π) Herculis 364 Ras Algethi (Alpha (α) Herculis) 285, 364 Rho (ρ) Herculis 364 Zeta (ζ) Herculis 364 95 Herculis 364 100 Herculis 364 Hercules Cluster (Abell 2151) 333, 364 Herdsman see Boötes Hermippe 181 Herschel, Caroline 215 Herschel, John 246 Herschel, William Cone Nebula 242 Eskimo Nebula 259 planetary nebulae 255 Polaris B 279 Saturn’s moons 193 Sombrero Galaxy 316 Uranus’s moons 203 Herschel crater (Mars) 152 Herschel Crateris (Mimas) 193, 193 Herschel Space Observatory 95, 306, 306 Herschel 36 243 Herschel’s Garnet Star (Mu (μ) Cephei) 232, 243, 243, 254, 287, 356, 356 Herse 181 Hertzsprung, Ejnar 232 Hertzsprung–Russell (H–R) diagram 232, 232 instability strip 255 main-sequence stars 232, 232, 251 star classification 233 star evolution 235, 235 Hevelius, Johannes 346, 384 Canes Venatici 362 Lacerta 369 Leo Minor 376 Lynx 359 Mira 285 Scutum 382 Sextans 396 Vulpecula 384 HH 320 240 HH 321 240 Hickson 92 (Stephan’s Quintet) 332 Hickson Compact Group 27 Hidalgo 171 Higgs bosons 48 high-mass stars life cycle 235, 236, 236 nuclear reactions 250 structure 250 supergiants 254 supernovae 234 high-velocity stars 229

Hillary 152 Himalayas (Earth) 132–33 Himalia 180 Himeros (Eros) 176–77 Hipparchus of Nicaea 70, 346 Hipparcos satellite 70, 70 Hiten space probe 141 Hoag’s Object (PGC 54559) 319 Hoba West meteorite 223 Hodge 301 311 Hoffmeister, Cuno 325 Homer 290, 390 Homunculus Nebula 262 Hooke, Robert 214, 371 Horologium (The Pendulum Clock) 419 Alpha (α) Horologii 419 Horsehead Nebula (Barnard 33) 240, 241, 391, 391 hot Jupiter exoplanets 298 Hourglass Nebula (MyCn18) 243, 263 Houtman, Frederick de 416 Apus 423 Chamaeleon 423 Dorado 421 Grus 417 Hydrus 419 Indus 416 Musca 413 Pavo 424 Phoenix 417 star catalog 346 Triangulum Australe 414 Tucana 418 Volans 422 HR 8799 298 H-R diagram see Hertzsprung– Russell diagram HST see Hubble Space Telescope Hubble, Edwin 45, 45, 301 Andromeda Galaxy 312, 313 galaxy classification 302, 302 Hubble 5 (Butterfly Nebula) 255 Hubble constant 44, 44 Hubble Space Telescope 45, 94, 94, 230, 244, 249, 297, 337 Pillars of Creation 244, 244 Hubble's Law 339 Humboldt Crater (Moon) 145 Hun Kal (Mercury) 112 Hunter see Orion Hunting Dogs see Canes Venatici Huron, Lake (Earth) 134, 134 Husband Hill 152 Huygens, Christiaan 99, 196 Huygens Crater (Mars) 164 Huygens lander 196, 196 Hyades (MEL 25) 290, 291, 372, 372 Aldebaran 256 in monthly sky guides 491, 496, 497 Hyakutake, Comet 80, 212, 215, 216 Hyakutake Yuji 80, 215 Hydra (the Water Snake) 394–95 see also Alphard (Alpha (α) Hydrae) Epsilon (ε) Hydrae 394 ESO 510-G13 318 M68 295, 394

Hydra cont. in monthly sky guides 442, 448, 449 Mu (μ) Hydrae 394 Hydra Cluster (Abell 1060) 332 Hydra, moon of Pluto 209 hydrogen 24 Big Bang 50, 50–51, 54 atomic number 29 galaxy superclusters 336–39 Bug Nebula 260 dark galaxies 326 first stars 55 intergalactic medium 327 interstellar medium 228 Jupiter 178, 178, 179, 180, 180 Lyman Alpha lines 338, 338 main-sequence stars 250, 251 Mercury 111 in meteorites 223 Moon 137, 149 nebulae 238 Neptune 204, 205 nuclear fusion 31, 31 planetary nebulae 255 properties 29 re-ionization 55 red giants 254, 254 Saturn 188 star formation 232, 234, 234, 238 stellar evolution 235, 236, 236 in Sun 104 supergiant stars 254 Uranus 201 Wolf–Rayet stars 255 hydrothermal vents 130 hydroxyl (OH) 215 Hydrus (the Little Water Snake) 419 Pi (π) Hydri 419 Hyginus 346, 346 hyperbolas, orbits 39 Hyperion 190, 197 hypernovae 37, 55 Hyrrokkin 191

I

Iapetus 190, 197 IC (Index Catalog) 73 IC 349 291 IC 405 359 IC 434 391 IC 1179 309 IC 1396 243 IC 2391 410, 410, 437 IC 2395 410, 437 IC 2602 (Southern Pleiades) 411, 443, 449 IC 2944 246 IC 4665 381, 466 IC 4703 (Eagle Nebula) 238, 244–45, 380, 380, 467 IC 4756 380 Icarus 170 ice Callisto 187 Earth 127, 127, 135, 135 Europa 183 Ganymede 186, 186 ice haloes 74, 74 Mars 150, 150, 153, 153, 161, 162, 162, 163 Neptune 204 Pluto 209, 209 Uranus 200

INDEX iron cont. high-mass stars 236 interstellar medium 228 Mercury 111 meteorites 223 old stars 236 supergiant stars 254 supernovae 266, 266 iron meteorites 170, 220 irregular clusters Abell 2125 333 Hercules Cluster 333 Local Group 328 Sculptor Group 329 Virgo Cluster 329 irregular galaxies 26, 305 Cigar Galaxy 314 classification 302, 302 distribution 306 Large Magellanic Cloud (LMC) 310–11 Small Magellanic Cloud (SMC) 311 Whirlpool Galaxy 315 irregular variable stars Gamma (γ) Cassiopeiae 285 R Coronae Borealis 287 Ishtar Terra (Venus) 117, 118 Isidis Planitia (Mars) 165 Islam, zodiac 64 islands, volcanic 130, 130, 131 Isonoe 181 Ithaca Chasma (Tethys) 194, 194 Itokawa 175 Izar (Epsilon (ε) Bootis) 25, 277, 363, 363, 460

J

January sky guide 430–35 Janus 192 Jarnsaxa 191 Jason and the Argonauts 371, 410 Jason Crater (Phoebe) 197 Jauslin, Karl 220 Jeanne Crater (Venus) 122 jets, superluminal 321, 321 Jewel Box (Kappa (κ) Crucis, NGC 4755) 294, 412, 412 in monthly sky guides 449, 455, 461 Job’s Coffin 385 John Sobieski, King of Poland 382 Juliet 201 July sky guide 466–71 June sky guide 460–65 Jupiter 178–87 atmosphere 180, 180 Comet Shoemaker–Levy 9 217 formation of Solar System 101 Great Red Spot 12–13, 181 magnetic field 179, 179 moons 13, 25, 180, 180–81, 182–87 occultations 69 orbit and spin 102, 178, 178 rings 181, 181 short-period comets 212 structure 178, 178 Trojan asteroids 170, 170 weather 181

K

k Puppis 409 K stars 233 Kachina Chasmata (Ariel) 203 Kailas Range (Earth) 132 Kale 181 Kallichore 180 Kalyke 181 Kant, Immanuel 100 Kappa (κ) Boötis 363 Kappa (κ) Coronae Australis 415 Kappa (κ) Crucis (Jewel Box, NGC 4755) 294, 412, 412 in monthly sky guides 449, 455, 461 Kappa (κ) Herculis 364 Kappa (κ) Leporis 407 Kappa (κ) Lupi 399 Kappa (κ) Pavonis 424 Kappa (κ) Tucanae 418 Kappa (κ) Velorum 410 Kapteyn, Jacobus Cornelius 229, 229 Karatepe (Mars) 166 Kari 191 Karl G. Janksy Very Large Array 91 Kasei Valles (Mars) 162 KBOs, Kuiper Belt Objects 208–10 Keck Telescope 91, 210 Keel see Carina Kemble, Lucian 358 Kemble’s Cascade 358, 358 Kennedy Space Center 9 Kepler, Johannes 68, 82, 175, 272 Kepler’s Star 273, 381 laws of planetary motion 102 Kepler mission 297, 299 Kepler–16/16b, star and exoplanet 298 Kepler–20e, 20f 299, 299 Kepler–22b 299, 299 Kepler’s Star (SN 1604) 37, 273, 381 Keyhole Nebula 247, 411 Keyser, Pieter Dirkszoon 416 Apus 423 Chamaeleon 423 Dorado 421 Grus 417 Hydrus 419 Indus 416 Musca 413 Pavo 424 Phoenix 417 star catalog 346 Triangulum Australe 414 Tucana 418 Volans 422 Keystone 364, 460, 466 Kirch, Gottfried 214 Kiviuq 190 Kiyotsugu, Hirayama 173 Kleinmann-Low Nebula 241 Knife Edge Galaxy 308 Köhler, Johann 317 Kore 181 Korolev, Sergei 148 Korolev Crater (Moon) 148 Koronis family, asteroids 173 Kowal, Charles 182 Kreutz, Heinrich 219 Kreutz sungrazers 219

Kuiper, Gerard 208 Miranda 202, 208 Neptune’s moons 206 Kuiper Airborne Observatory 201, 201 Kuiper Belt 208–11 Classical Kuiper Belt 210 Objects 208–10 Pluto 208, 209

L

L Puppis 409 L2 Puppis 409 Lacaille, Nicolas Louis de 346, 422 Antlia 396 Caelum 405 Circinus 413 Horologium 419 Mensa 422 Microscopium 403 NGC 4833 295 Norma 414 Octans 425 Pictor 420 Pyxis 408 Reticulum 420 Sculptor 404 Telescopium 416 Lacerta (the Lizard) 369 BL Lacertae (BL Lac) 325, 369 Lada Terra (Venus) 121 Laelaps 392 Lagoon Nebula (M8) 243, 400, 400 binocular astronomy 81 in monthly sky guides 467, 473, 473 Lagrange (Lagrangian) points, orbits 95, 194 lakes, on Earth 132, 134 Lakshmi Planum (Venus) 118 Lalande, J.J. 397 Lambda (λ) Aquilae 383 Lambda (λ) Arietis 371 Lambda (λ) Cepheus 356 Lambda (λ) Tauri 284, 372 Lambda (λ) Velorum 410 Langren, Arnold van 346–47 Laomedeia 205 Laplace, Pierre-Simon de 100 Large Binocular Telescope 91 Large Hadron Collider 52–53 Large Magellanic Cloud (LMC) 305, 310–11, 421, 421 MACHO 96 273 Milky Way halo 229 in monthly sky guides 431, 437, 443, 485, 490, 491, 497, 497 supernova 265 Larissa 205, 206 Larsen Ice-shelf (Earth) 135 laser guide star 91 Lassell, William 203, 206, 207, 207 Lassell ring (Neptune) 205, 205 Latin names, constellations 72 latitude, and celestial sphere 62 lava flows Io 184 Mars 152, 157, 160, 160 Mercury 112 Moon 137, 138, 144 Venus 116–21 LCROSS mission 141, 149

Le Verrier, Urbain 102 Le Verrier ring (Neptune) 205, 205 lead, formation of 55 Leavitt, Henrietta 286, 311, 356 Leda 180 Leda, Queen of Sparta 367, 374 Lemaître, Georges 50 lenses 80, 82 lensing see gravitational lensing lenticular clouds 75 lenticular galaxies 26, 304 classification 302, 302 Spindle Galaxy 317 Leo (the Lion) 72, 347, 377 Algieba (Gamma (γ) Leonis) 377, 377 Denebola (Beta (β) Leonis) 72 in monthly sky guides 436, 437, 442, 442, 443, 448, 449, 455, 460 Zeta (ζ) Leonis 377 40 Leonis 377 see also Regulus (Alpha (α) Leonis) Leo I galaxy 304 Leo Minor (the Little Lion) 376 Beta (β) Leonis Minoris 376 46 Leonis Minoris 376 Leonid meteor shower 220, 220, 377, 426–27, 490 Lepton Era 50 leptons 31 after Big Bang 50, 50 Lepus (the Hare) 407 Gamma (γ) Leporis 407 Kappa (κ) Leporis 407 R Leporis 407 Levy, David 217 LHC, Large Hadron Collider 52–53 Libra (the Scales) 379 Delta (δ) Librae 379 Iota (ι) Librae 379 Mu (μ) Librae 379 sky guide 449 Zubenelgenubi (Alpha (α) Librae) 379 Zubeneschamali (Beta (β) Librae) 379 life 56–57 extra-solar planets 299, 299 water and 127 life cycles, stars 234–37 light 34 after Big Bang 54 analyzing 35, 35 black holes 267 emission nebulae 24, 24 expanding space 45, 339 galaxies 305 gravitational lensing 267, 273, 297, 306, 327, 327, 334–35 gravity 42, 42, 43 ice haloes 74, 74 inverse square law 71 light pollution 76, 85 observable Universe 23 Olbers’ paradox 51 optical telescopes 37, 37, 82–87 photoelectric effect 34, 34 red shift 44 space and time 40–41 stars 25 velocity of 34, 40, 41 wave-like behavior 34, 34 light grasp 83

I N D EX

ice ages 124 ice dwarfs 25 IceCube Neutrino Observatory 32–33 Ida 100, 170, 173 Ijiraq 190 Ikeya Kaoru 214 Ikeya–Seki, Comet 214, 219 Ikeya–Zhang, Comet 25 image processing, in astrophotography 89, 89 Imbrium Basin (Moon) 144 impact craters asteroids 171, 171 Callisto 187 formation 103 Mars 152, 164–67 Mercury 112, 112, 113, 113 meteorites 221, 221 Miranda 202 Moon 137, 139, 144–45, 148–49 moons 213 ray craters 139 Venus 117, 117, 122–23 Vesta 174 impactites 221 Incas 67 Indus (the Indian) 416 Epsilon (ε) Indi 416 Theta (θ) Indi 416 inferior planets, motion 68, 68, 69 inflation theory, Big Bang 48, 48 infrared 34 astronomy from space 95 galaxies 305 telescopes 36, 36 instability strip, Hertzsprung– Russell (H–R) diagram 255 interference, light waves 34, 34 intergalactic medium 327 intermediate-period comets 212 International Astronomical Union 347 International Comet Explorer 217 International Space Station (ISS) 75, 219 International Ultraviolet Explorer 94 interstellar medium 24, 28 early Universe 55 Milky Way 228 radio astronomy 91, 91 star formation 234, 239 inverse square law 71 Io 13, 25, 180, 182, 184–85 Iocaste 181 ions 28, 28 ionic compounds 29, 29 plasma 30 Sun 106 Iota (ι) Canceri 375 Iota (ι) Carinae 411 Iota (ι) Librae 379 Iota (ι) Normae 414 Iota (ι) Orionis 391 Iota (ι) Pictoris 420 IRAS telescope 253 IRAS 18059-3211 (Gomez’s Hamburger Nebula) 262 iron Earth 124 formation of 29, 55

517

I ND E X

518

INDEX light-year 22 lightning 75, 75 lights in the sky 74–75 line-of-sight binaries 274 Lion see Leo Lippershey, Hans 82 liquids, states of matter 30 lithium 51 lithosphere, Earth 126, 126 Little Bear see Ursa Minor Little Dipper 354, 460, 466 Little Dog see Canis Minor Little Lion see Leo Minor Little Water Snake see Hydrus Lizard see Lacerta Lob Crater (Puck) 202 Local Bubble, Milky Way 229, 229 Local Group 23, 27, 326, 326, 328, 336 Andromeda Galaxy 312 galaxy superclusters 336, 336 Local Interstellar Cloud 229 Local Supercluster 23, 336 Loge 191 long-period comets 208, 210–11, 212 lookback distance 45, 45 Loop I, Milky Way 229 Loop II, Milky Way 229 Loop III, Milky Way 229 Lorentz contraction 41, 41 Lovejoy, Comet 219 Lovejoy, Terry 219 low-mass stars life cycles 235, 236, 236 structure 250 low-surface-brightness galaxies Malin 1 319 Lowell Crater (Mars) 165 Lowell Observatory 209, 316 luminosity 71, 233 Hertzsprung–Russell (H–R) diagram 232, 232 main-sequence stars 251 pulsating variable stars 282 stellar classification 233 Type I supernovae 283 lunar eclipses 67, 67 lunar month 66 Lunar Prospector 139, 141, 149, 149 Lunar Reconnaissance Orbiter 140, 149 Lunar Rover 138, 146 Lunik (Luna) space probes 139, 139, 141 Lupus (the Wolf) 399 Epsilon (ε) Lupi 399 Eta (η) Lupi 399 Kappa (κ) Lupi 399 in monthly sky guides 461 Mu (μ) Lupi 399 Pi (π) Lupi 399 Xi (ξ) Lupi 399 Lutetia 172 Lyman Alpha blobs 388 Lyman Alpha lines and forest 338, 338 Lynx (the Lynx) 359 12 Lyncis 359 19 Lyncis 359 38 Lyncis 359 Lyons, Harold 41 Lyra (the Lyre) 365 Beta (β) Lyrae (Sheliak) 281, 365 Delta (δ) Lyrae 365

Lyra cont. Epsilon (ε) Lyrae 276, 365 Gamma (γ) Lyrae 365 M40 277 Ring Nebula 257, 365, 365, 472, 473 RR Lyrae 286 see also Vega (Alpha (α) Lyrae) Zeta (ζ) Lyrae 365 Lyrid meteor shower 365, 448 Lysithea 180

M

M stars 233 M1 (Crab Nebula) 270–71, 372, 372 M2 387, 479 M2-9 (Twin Jet Nebula) 257 M3 25, 73, 362 M4 272, 294, 402 M5 380, 380, 460, 466 M6 see Butterfly Cluster M7 402, 402, 461, 461, 467, 473 M8 see Lagoon Nebula M9 292–93 M10 381, 381, 466 M11 (Wild Duck Cluster) 382, 382, 472, 473 M12 295, 381, 466 M13 57, 364, 364, 460, 466 M14 295 M15 295, 386, 387, 478, 479 M16 244, 380, 467, 473 M17 (Omega Nebula) 240, 400, 401 M20 (Trifid Nebula) 246, 400, 400, 467 M22 400, 400, 467, 473 M23 400 M24 400, 467 M25 400 M27 (Dumbbell Nebula) 257, 384, 384, 472, 473 M30 403, 403 M31 see Andromeda Galaxy M32 302, 313, 328, 368, 368 M33 (Triangulum Galaxy) 302, 311, 328, 369, 369, 485, 491 M34 370 M35 83, 374, 374, 436 M36 359, 430, 430 M37 359, 430, 430 M38 359, 430, 430 M39 288, 367, 367, 478 M40 277 M41 392, 431, 431, 437 M42 see Orion Nebula M43 241, 391 M44 see Beehive Cluster M46 409, 409, 437 M47 409, 437 M48 394 M49 304, 329, 378 M50 393 M51 (Whirlpool Galaxy) 14, 302, 315, 362, 362, 454, 460 M52 290, 357, 357, 484 M54 310 M57 (Ring Nebula) 257, 365, 365, 472, 473 M59 302 M60 317

M63 (Sunflower Galaxy) 362, 362 M64 (Black Eye Galaxy) 314, 376, 376 M65 377, 377 M66 377, 377 M67 375, 375 M68 295, 394 M69 378 M71 382 M74 37, 388, 388 M77 389, 389, 491 M79 407, 407 M81 (Bode’s Galaxy) 26, 73, 314, 360, 360, 442, 448 M82 (Cigar Galaxy) 73, 305, 314, 360 M83 (Southern Pinwheel) 302, 394, 394, 455, 461 M84 329, 329, 378 M85 376 M86 329, 329, 378 M87 304, 330–31, 323, 329, 378, 378 M88 376 M89 302 M90 37 M92 364 M93 290, 290, 409, 409 M94 362 M95 377 M96 377 M97 73, 360, 360 M99 376 M100 376 M101 (Pinwheel Galaxy) 316, 360, 454, 460 M102 (Spindle Galaxy) 317, 396, 396 M103 357, 357 M104 (Sombrero Galaxy) 316, 378, 378 M105 377 M106 320 M107 295 M108 73 M109 73 M110 302, 313, 328, 368, 368 Maat Mons (Venus) 116, 116, 120, 120 Mab 201 MACHOs (massive compact halo objects) 27, 96 273 Maffei group, galaxy superclusters 336 Maffei 1 329 Magellan, Ferdinand 310, 311, 311 Magellan space probe 116, 117 Magellan spectrograph 297 Magellanic Clouds see Large Magellanic Cloud (LMC); Small Magellanic Cloud (SMC) Magellanic Stream 311 MAGIC Telescope 91 magma, plate tectonics 130 magnesium, on Earth 124 magnetic fields aurorae 74 black holes 320 Earth 125, 125 electromagnetic (EM) radiation 34 Jupiter 179, 179 Mercury 111 Milky Way 228 Neptune 204

magnetic fields cont. neutron stars 267 pulsars 267 Saturn 188 stars 251 Sun 10, 106, 107, 108–109 synchrotron mechanism 320 Uranus 200 magnetosphere Earth 125, 125 Jupiter 179, 179 magnification binoculars 80, 81 telescopes 83, 83, 85 magnitude see absolute magnitude; apparent magnitude Maia 291 Main Belt, asteroids 103, 170, 170 main-sequence stars 250–53 Alpha (α) Centauri 252, 274 Altair (Alpha (α) Aquilae) 252 classification 233 energy 250 evolution 235, 235, 236 Fomalhaut (Alpha (α) Piscis Austrini) 253 Hertzsprung–Russell (H–R) diagram 232, 232, 251 magnetism 251 Porrima (Gamma (γ) Virginis) 253 Proxima Centauri 252 Regor (Gamma (γ) Velorum) 253 Regulus (Alpha (α) Leonis) 253 rotation 251, 251 Sirius A (Alpha (α) Canis Majoris) 252 structure 250, 250 Vega (Alpha (α) Lyrae) 253 61 Cygni 252 Malin 1 319 Makemake 210 Manger Cluster see Beehive Cluster mantle Earth 124, 124 Mars 150, 150 Mercury 111, 111 Moon 136, 136 Neptune 204, 204 Uranus 200, 200 maps mapping the sky 348–49 mapping the Universe 339, 339 March sky guide 442–47 Marcy, Geoffrey 299 Mare Crisium (Moon) 144 Mare Imbrium (Moon) 139 Mare Orientale Crater (Moon) 140, 149 Mare Serenitatis (Moon) 144, 146 Mare Tranquillitatis (Moon) 144 Margaret 201 maria, Moon 137 Mariner space probes Mars 159 Mercury 112 Venus 116 Marius, Simon 182–83, 184 Mars 150–69 asteroids 170, 170 atmosphere 151, 151

canyons 13 dunes 154–55 features formed by water 160–63 impact craters 152, 164–67 maps 152–53, 153 meteorites from 157, 157, 222 moons 153, 153 Noctis Labyrinthus 154–55 orbit and spin 102, 150, 150 retrograde motion 68, 68 search for life 57 space probes 152, 159 structure 150, 150 surface features 152 tectonic features 152, 156–60 water 153, 153 Mars Exploration Rovers 152, 152 Mars Express 152, 153, 159, 159 Mars Global Surveyor 150, 152, 153, 153, 159 Mars Pathfinder 152 Mars Reconnaissance Orbiter 151, 152, 157, 164, 169 Marsden, Brian 218 mass and energy 41, 41 fate of Universe 58–59 galaxy clusters 327, 335, 335 gravitational lensing 306, 327 laws of gravity 38 and luminosity 233 main-sequence stars 250, 251 neutron stars 267 nuclear reactions 232 and space-time 42–43 42–43 star evolution 235 star formation 238 stellar endpoints 266 stellar structure 250 white dwarfs 266 massive stars, death of 266, 266 Mathilde 172 matter 24, 28–31 antimatter 31, 321, 321 atoms 28, 28–29 Big Bang 48–51 Big Chill 59 black holes 267 chemical compounds 29, 29 chemical elements 29 see also dark matter development of structures 54, 54 forces 30, 30 particle physics 31 states of matter 30 Mauna Kea Observatory, Hawaii 206 Maximilian, Emperor 222 Maxwell, James Clerk 118 Maxwell Montes (Venus) 116, 117, 118, 122 May sky guide 454–59 McNaught, Comet 219 McNaught, Robert 219 Mead Crater (Venus) 123 measurements see distance Méchain, Pierre 73, 215 Medea, in mythology 371 Medusa, in mythology 370, 386 Megaclite 181 Mekbuda (Zeta (ζ) Geminorum) 286, 374 MEL 25 see Hyades

INDEX methane cont. Titan 196 Uranus 200, 201, 201 Methone 190, 192 Methuselah 272 Metis 180, 182 the Mice (NGC 4676) 318 Michigan, Lake (Earth) 134 Microscope see Microscopium Microscopium (the Microscope) 403 Alpha (α) Microscopii 403 AU Microscopii 296 microwaves 34 cosmic microwave background radiation (CMBR) 36, 51, 54, 95, 334, 337 microwave observatories 36, 36, 95 Mid-Atlantic Ridge (Earth) 130 midnight Sun 64–65 Milk Dipper 400 Milky Way 26, 78–79, 224–99, 230–31, 328 activity 321 binocular astronomy 81 black hole 14, 226 Cygnus Rift 367, 472 dark matter 229, 268 galactic center 36, 229 globular clusters 289, 289 halo 229, 273 interstellar medium 228 Local Group 328 in monthly sky guides 430, 437, 472 old stars 256 Omega Centauri 294 open star clusters 288, 289 size 22 sky guides 430, 437, 472, 496 star clusters 290 star formation 240 stellar end points 266–73 Miller, Stanley 56, 56 Milton, John 225 Mimas 190, 192, 193 minerals, on Earth 124, 125 Mira (Omicron (ο) Ceti) 285, 389, 490, 491, 491 Miralaidjii Corona (Venus) 121 Miranda 201, 202, 208 Mirphak (Alpha (α) Persei) 232, 370, 496 mirrors, telescopes 82, 91 Mizar (Zeta (ζ) Ursae Majoris) 72, 276, 360, 361, 454 Mneme 181 MODIS instrument 128–29 moldavite 221 molecular clouds 240 see also dark nebulae star formation 228, 234, 234, 238 Molecular Ring, Milky Way 229 molecules 29 monerans 127 Mongols 279 Monoceros (the Unicorn) 393, 436 Alpha (α) Monocerotis 393 Beta (β) Monocerotis 281, 393 Cone Nebula 242, 280, 393, 393 Red Rectangle Nebula 258

Monoceros cont. S Monocerotis 242, 393 V838 Monocerotis 265, 282–83 8 Monocerotis 393 15 Monocerotis 280 Montes Apenninus (Moon) 144 Montes Cordillera (Moon) 149 Montes Rook (Moon) 149 monthly sky guides 426–501 months, measuring 66 Moon 9, 83, 88, 136–49 angular diameter 77 Apollo missions 142–43, 144 astrology 64 atmosphere 137, 137 Earthrise 142–43 eclipses 67 far side 141 features 144–49 formation 137, 137 Galileo’s observations 82 gravity 38 Harvest Moon 478 history 137 ice haloes 74, 74 impact craters 137, 139, 148–49 influence on Earth 138, 138 maps 139 meteorites from 222, 223, 223 movements across sky 63 near side 140 occultations 69, 69, 253 orbit and spin 39, 136, 136 phases 66, 66 size 22 space probes 139, 141 see also individual named probes, satellites and spacecraft structure 136, 136 surface features 138, 138 moon dogs 74, 74 moons 25 Jupiter 13, 25, 180, 180–81 182–87 Mars 153, 153 Neptune 205, 205, 206–207 Pluto 209, 209 Saturn 190, 190–91, 192–97 Uranus 201, 202–203 Morecambe Bay (Earth) 138 MOST space telescope 297 motion accelerating 42, 42, 339 celestial sphere 62–63, 62–63 Newton’s laws 38, 38 planets 68–69 retrograde 68, 68 stars 70 Mount Palomar, California 90 mountains Earth 131, 132 Moon 146 mountings, telescopes 83, 83, 86, 86 moving clusters 360 moving lights, in sky 75 Mu (μ) Boötis 363 Mu (μ) Cephei (Garnet Star) 232, 243, 243, 254, 287, 356, 356 Mu (μ) Columbae 408 Mu (μ) Crucis 412 Mu (μ) Draconis 355 Mu (μ) Gruis 417, 417 Mu (μ) Hydrae 394

Mu (μ) Librae 379 Mu (μ) Lupi 399 Mu (μ) Scorpii 402 multiple stars 274–81 Mundilfari 191 Mundrabilla meteorite 223 Musca (the Fly) 413 BHR 71 240 Hourglass Nebula 263 NGC 4833 295, 413 Theta (θ) Muscae 413 MyCn18 (Hourglass Nebula) 243, 263 myths, Moon 138

N

N44C 255 Naiad 205 naked-eye astronomy 76–77 Nakhla meteorite 222 names constellations 72 stars 72, 346 Nanedi Valles (Mars) 162 Nansen, Fridtjof 165 Nansen Crater (Mars) 165 Naos (Zeta (ζ) Puppis) 409 NASA Deep Space 1 mission 217 Discovery program 176 Lunar Orbiters 139, 139 Stardust mission 172, 217, 218 navigation, Pole Star 279 Near Earth Asteroid Rendezvous (NEAR) space probe 176 NEAR Shoemaker probe 172 Nebra Disk 291, 291 Nebuchadnezzar, King of Babylon 138 nebulae 24 BHR 71 240 bubble nebulae 264 Carina Nebula 247, 248–49 catalogs 73 Cone Nebula 242 dark nebulae 24, 228, 240 DR 6 243 DR 21 246 Eagle Nebula 244–45 emission nebulae 24, 35, 228, 240 Horsehead Nebula 240 IC 1396 243 IC 2944 246 Lagoon Nebula 243 Orion Nebula 241 see also planetary nebulae RCW 49 247 reflection nebulae 239 spectroscopy 35 star-forming nebulae 25, 238, 240–47 Trifid Nebula 246 neon, in Moon’s atmosphere 137 Neptune 204–207 atmosphere and weather 204, 204, 205, 205 and Kuiper Belt 208 moons 205, 205, 206–207 orbit and spin 103, 204, 204 and Pluto 209 rings 205, 205 structure 204, 204 Nereid 205, 205, 206, 208

Nereidum Montes (Mars) 165 Neso 205 Net see Reticulum neutrinos 28, 30, 31, 104 after Big Bang 50, 50, 54 Big Chill 59 detectors 27, 27, 32–33 neutron stars 25, 235, 267 formation 236, 236, 237 gamma-ray astronomy 37 Geminga Pulsar 268 PSR B1620-26 272 RX J1856.5-3754 268 space-time 43 neutrons 28, 28–29 after Big Bang 50, 50 forces 30, 30 New General Catalog see NGC Newton, Isaac 38, 82 Great Comet of 1680 214 law of universal gravitation 38, 68 laws of motion 38, 38, 110 telescope 82, 82 Newton Crater 153 Newtonian telescopes 82 Newtonian universe, space and time 40 NGC (New General Catalog) 26, 73, 239 NGC 55 329, 404 NGC 104 (47 Tucanae) 294, 311, 418, 418, 479, 485, 491 NGC 224 see Andromeda Galaxy NGC 253 329, 329, 404 NGC 288 404 NGC 292 see Small Magellanic Cloud (SMC) NGC 362 418, 485 NGC 383 320 NGC 457 357, 490 NGC 520 (Arp 157) 308 NGC 598 (Triangulum Galaxy) 302, 311, 328, 369, 369, 485, 491 NGC 604 311, 311 NGC 660 302 NGC 663 357, 490 NGC 752 368 NGC 869 370, 370, 490, 496 NGC 884 370, 370, 490, 496 NGC 1261 419, 419 NGC 1275 324 NGC 1300 302, 406, 406 NGC 1316 306, 329, 405 NGC 1365 329, 405, 405 NGC 1399 329, 405 NGC 1427A 239 NGC 1435 see Pleiades NGC 1502 358, 358 NGC 1530 26, 26 NGC 1851 408 NGC 1952 (Crab Nebula) 270–71, 372, 372 NGC 1976 see Orion Nebula NGC 1977 (Ghost Nebula) 89, 391 NGC 1981 391 NGC 2017 407, 407 NGC 2070 see Tarantula Nebula NGC 2158 374 NGC 2232 393 NGC 2244 393, 393, 436 NGC 2264 (Cone Nebula) 242, 280, 393, 393 NGC 2264 IRS 242 NGC 2266 254, 289

I N D EX

Melas Chasma (Mars) 159 Melotte 20 370 Melotte 111 (Coma Star Cluster) 376, 448, 454 Menkar (Alpha (α) Ceti) 389 Mensa (the Table Mountain) 422 Alpha (α) Mensae 422 Menzel 3 (Ant Nebula) 259 Merak (Beta (β) Ursae Majoris) 72, 77, 360 Mercator, Gerardus 376 Mercury 110–13 atmosphere 111, 111 geography 112 map 112 motion 68 orbit and spin 43, 102, 102, 110, 110 space probes 112 structure 111, 111 surface features 112, 112 transits 69, 110 Mercury Surface, Space Environment, Geochemistry and Ranging mission (MESSENGER) 112 meridian, celestial 63 Meridiani Planum (Mars) 163, 166, 167 Merope 291, 291 Merope, in mythology 373 mesas, on Mars 158, 164 mesons 31, 50 mesosphere, Earth’s atmosphere 126 Messenger space probe 111, 112 Messier, Charles 73 Crab Nebula 271 Eagle Nebula 244 Pinwheel Galaxy 316 Sombrero Galaxy 316 Spindle Galaxy 317 Whirlpool Galaxy 315 metallic (M-type) asteroids 170 Meteor Crater (Arizona) 221, 222 meteor showers 220 Delta Aquarid 467 Eta Aquarid 387, 454, 455 Geminid 374, 496, 496 Leonid 220, 220, 377, 426–27, 490 Lyrid 365, 448 Orionid 390, 484 Perseid 214, 220, 472, 472 Quadrantid 363, 430 Taurid 372, 490 meteorites 170, 220–23 in Antarctica 135, 221 impact craters 103 from Mars 157, 157 on Mars 163 Moon craters 137 from Vesta 174 meteoroids 25, 220 see also meteor showers meteors 75, 88, 220–23, 221 methane atomic structure 29 extra-solar planets 299 Jupiter 180 Kuiper Belt Objects 208–10 Neptune 204 Pluto 209 Saturn 189

519

I ND E X

520

INDEX NGC 2359 264 NGC 2362 392, 392 NGC 2392 (Eskimo Nebula) 259, 374, 374 NGC 2403 358 NGC 2440 nucleus (HD 62166) 268 NGC 2447 290 NGC 2451 409, 437 NGC 2467 238 NGC 2477 409, 409, 437 NGC 2516 411, 437 NGC 2547 410 NGC 2736 (Vela Supernova) 269, 410 NGC 2755 302 NGC 2787 304 NGC 2841 73 NGC 2997 396, 396 NGC 3031 (Bode’s Galaxy) 314, 360, 360 NGC 3034 (Cigar Galaxy) 73, 305, 314, 360 NGC 3079 73 NGC 3114 411 NGC 3115 (Spindle Galaxy) 317, 396, 396 NGC 3132 (Eight-Burst Nebula) 254–55, 410, 443 NGC 3195 423 NGC 3201 294 NGC 3242 (Ghost of Jupiter) 394, 394 NGC 3309 332 NGC 3311 332, 332 NGC 3312 332 NGC 3314 332 NGC 3372 see Carina Nebula NGC 3532 411, 411 NGC 3603 234 NGC 3628 377 NGC 3766 398 NGC 3918 (Blue Planetary) 398 NGC 4038 and 4039 (Antennae Galaxies) 37, 309, 317, 318, 397, 397 NGC 4261 323 NGC 4414 303 NGC 4438 26 NGC 4449 305 NGC 4472 307 NGC 4486 323 NGC 4526 283 NGC 4565 376, 376 NGC 4590 295 NGC 4594 (Sombrero Galaxy) 316, 378, 378 NGC 4621 307 NGC 4622 302 NGC 4649 317 NGC 4650A 305 NGC 4676 (the Mice) 318 NGC 4755 (Jewel Box) 294, 412, 412, 449, 455, 461 NGC 4826 (Black Eye Galaxy) 314, 376 NGC 4833 295, 413 NGC 4881 332 NGC 4889 326, 332 NGC 5128 see Centaurus A NGC 5139 see Omega Centauri NGC 5194 and NGC 5195 (Whirlpool Galaxy) 14, 302, 315, 362, 454, 460 NGC 5457 (Pinwheel Galaxy) 316, 360, 454, 460 NGC 5460 398 NGC 5548 323

NGC 5822 399, 399 NGC 5866 317 NGC 5907 308 NGC 6025 414 NGC 6027 and NGC 6027A-C (Seyfert’s Sextet) 308, 329 NGC 6041A 333 NGC 6050 308, 333 NGC 6087 414, 414 NGC 6121 294 NGC 6128 295 NGC 6171 295 NGC 6193 415 NGC 6231 402, 461 NGC 6302 (Bug Nebula) 260–61 NGC 6397 289, 415, 415 NGC 6402 295 NGC 6405 see Butterfly Cluster NGC 6514 246, 246 NGC 6523 243 NGC 6530 243, 400, 467 NGC 6541 415 NGC 6543 (Cat’s Eye Nebula) 258, 355, 355 NGC 6633 381, 466 NGC 6744 424, 424 NGC 6751 25, 255 NGC 6752 424, 424 NGC 6782 318 NGC 6822 (Barnard’s Galaxy) 328 NGC 6826 367 NGC 6888 (Crescent Nebula) 259 NGC 6960/95 (Cygnus Loop) 228, 269 NGC 6992 367 NGC 7000 (North America Nebula) 367, 367, 478 NGC 7009 (Saturn Nebula) 255, 387, 387, 479 NGC 7078 295 NGC 7293 (Helix Nebula) 257, 387, 387, 479 NGC 7320 332, 332 NGC 7479 302 NGC 7654 290 NGC 7662 (Blue Snowball) 368, 368, 484 NGC 7742 (Fried Egg Galaxy) 323 Niagara Falls (Earth) 134 Nicholson Regio (Ganymede) 186 nickel Earth 124 meteorites 222, 223 nitrogen Bug Nebula 260 Earth’s atmosphere 126 main-sequence stars 250 meteorites 223 planetary nebulae 255 Pluto 209, 209 Titan 196 Wolf–Rayet stars 255 Nix 209 Noachis Terra Crater 151 Noah 408 noctilucent clouds 75, 75, 460 Noctis Labyrinthus (Mars) 154–55, 158 Norma (the Set Square) 414, 461 Ant Nebula 259 Epsilon (ε) Normae 414

Norma cont. Gamma-1 (γ1) Normae 414 Gamma-2 (γ2) Normae 414 Iota (ι) Normae 414 Norse mythology, Polaris 279 North America Nebula (NGC 7000) 367, 367, 478 north celestial pole 62 North Polar Region (Mars) 153, 161 North Polar sky 348 Northern Coalsack 367 Northern Cross see Cygnus Northern Crown see Corona Borealis Northern Lights 107 novae 282 binocular astronomy 80 Nova Cygni 1992 282, 287 RS Ophiuchi 287 T Coronae Borealis (Blaze Star) 286 November sky guide 490–95 Nu (ν) Boötis 363 Nu (ν) Coronae Borealis 379 Nu (ν) Draconis 355 Nu (ν) Scorpii 402 nuclear fission 31 nuclear fusion 31, 31 inside stars 232, 234, 234 main-sequence stars 250 protostars 239 star formation 238 Sun 104 nucleons 30 Nucleosynthesis Era 50 nucleus, atom 28, 29 after Big Bang 50 forces 30, 30

O

O stars 233, 255 O3 stars 247 OB stars 241 Oberon 201, 203 observable Universe 23 observatories 90–95, 90–95 see also individual named observatories, telescopes occultation 69, 253 oceans (Earth) 127, 127 tides 138, 138 Octans (the Octant) 425 Delta (δ) Octantis 425 Sigma (σ) Octantis 425 Octant see Octans October sky guide 484–89 Odysseus Crater (Tethys) 194 OH231.8+4.2 (Calabash Nebula) 262 oil reserves, on Earth 135 Okmok volcano (Earth) 131 Olbers, Heinrich 175 Olber’s paradox 51 old stars 254–65 globular clusters 289 Olympus Mons (Mars) 152, 152, 156, 156, 157 OMC-1 241 Omega Centauri (NGC 5139) 288, 290, 294, 398 binocular astronomy 81 density 289 in monthly sky guides 418, 449, 455, 461

Omega Nebula (M17) 240, 400, 401 Omega (ω) Scorpii 402 Omicron (ο) Ceti (Mira) 285, 389, 490, 491, 491 Omicron (ο) Cygni 366 Omicron (ο) Draconis 355 Omicron (ο) Eridani 276, 406, 406 Omicron (ο) Velorum 410 On the Revolution of the Heavenly Spheres 69 Ontario, Lake (Earth) 134 Oort, Jan Hendrik 211 Oort Cloud 208–11 Opaque Era 51 open clusters 288, 290 Beehive Cluster 290 Butterfly Cluster 290 evolution 289, 289 Hyades 290 Jewel Box (Kappa (κ) Crucis) 294 M52 290 M93 290 Pleiades 291 open universe 59, 59 Ophelia 201, 202 Ophir Chasma (Mars) 159, 159 Ophiuchus (the Serpent Holder) 380, 381 Barnard’s Star 70, 381 Cygnus Rift 367, 472 Kepler’s Star 37, 273, 381 M12 295, 381, 466 M14 295 M107 295 in monthly sky guides 466, 472 Rho (ρ) Ophiuchi 296, 381, 381 RS Ophiuchi 287 Twin Jet Nebula 257 Zeta (ζ) Ophiuchi 268 36 Ophiuchi 381 70 Ophiuchi 381 Opik, Ernst 211 Opportunity rover, on Mars 164, 166–67 opposition, planets 68 optical telescopes 37, 37, 82–87 orange stars Alpha (α) Centauri (Rigil Kentaurus) 252, 274 61 Cygni 252 orange-red stars Proxima Centauri 252 Orbiting Astronomical Observatory 94 orbits asteroids 170, 170–71 comets 212, 212 elliptical galaxies 304 globular clusters 289 Jupiter 178, 178 Kuiper Belt objects 208–10 Lagrange points 194 Mars 150, 150 Mercury 43, 110, 110 Moon 136 multiple stars 274, 274 Neptune 204, 204 Pluto 209, 209 Saturn 188, 188 Sedna 211 shapes of 39, 39 Solar System 102–103 space-time 42–43, 42–43

orbits cont. spiral galaxies 302 synchronous rotation 136 Uranus 200, 200 Venus 114, 114 Orion (the Hunter) 72, 390–91 Alnilam (Epsilon (ε) Orionis) 232 Alnitak (Zeta (ζ) Orionis) 232, 390, 391, 391 Bellatrix (Gamma (γ) Orionis) 71 Delta (δ) Orionis 390 Ghost Nebula 89 Horsehead Nebula 240, 241, 391, 391 Iota (ι) Orionis 391 mythology 390, 402 in monthly sky guides 431, 436, 437, 442, 443, 496, 497 naked-eye astronomy 77, 77 Orion’s belt 72, 390, 431 Sigma (σ) Orionis 240, 281, 390, 391 star colors 70–71 see also Betelgeuse (Alpha (α) Orionis); Rigel (Beta (β) Orionis) Trapezium (Theta (θ) Orionis) 241, 241, 275, 276, 281, 391, 391 42 Orionis 391 45 Orionis 391 Orion Arm, Milky Way 227, 229, 229 Orion Nebula (M42, NGC 1976) 14–15, 241, 310, 390, 391, 391 binocular astronomy 81, 81 bow shock 20–21 in monthly sky guides 430, 431, 431 Theta (θ) Orionis 281 young stars 55 Orionid meteor shower 390, 484 Orpheus, mythology 365 Orthosie 181 Ovda Regio (Venus) 121 Overwhelmingly Large Telescope (OWL) 37 Owl Nebula 360, 360 oxygen Earth’s atmosphere 126, 126 extra-solar planets 299 formation 29, 55 main-sequence stars 250 Mercury 111, 111 meteorites 223 planetary nebulae 255 silicates 24 supergiants 254 Type I supernovae 283 Wolf–Rayet stars 255 Ozza Mons (Venus) 120

P

P4 (S/2011 P1) 209 Paaliaq 191 Pacific Ocean (Earth) 8 Pacific Ring of Fire (Earth) 131 Painter’s Easel see Pictor Palermo Circle 175 Palisa, Johann 173 Palomar Observatory 90 Pallas 175

INDEX Perseus (the Victorious Hero) 95, 370 Algol (Beta (β) Persei) 276, 370, 370, 496 Mirphak (Alpha (α) Persei) 232, 370, 496 in monthly sky guides 430, 436, 437, 490, 490, 496, 497 NGC 1275 324 Rho (ρ) Persei 370 Perseus, in mythology 368, 370 Pettifor, Arthur 222 PG 0052+251 320 PGC 54559 (Hoag’s Object) 319 PGC 54876 333 Phad (Gamma (γ) Ursae Majoris) 72, 360 Phaethon, in mythology 406 phases Moon 66, 66 planets 68 Phi (ϕ) Cassiopeiae 357 Philae lander 217 Phobos 153, 153 Phoebe 191, 197 Phoenix 417, 479 Zeta (ζ) Phoenicis 417 photoelectric effect 34, 34 photo-evaporation 244 photography, astro– 88–89 photons 28 absorption lines 35 after Big Bang 50, 50–51, 54 Big Chill 59 electromagnetic force 30 energy 34 radiation 250 Sunyaev–Zel’dovich effect 334 photosphere stars 250, 250 Sun 104, 106, 106, 107 physics gravity 38–39 laws of motion 38, 38 laws of planetary motion 68 matter 28–31 radiation 34–37 space and time 40–43 Pi (π) Aquarii 387 Pi (π) Arietis 371 Pi (π) Herculis 364 Pi (π) Hydri 419 Pi (π) Lupi 399 Piazzi, Giuseppe 385 Ceres 171, 175 telescope 175 Piccolomini Crater 145 Pictor (the Painter’s Easel) 420 Beta (β) Pictoris 296, 420, 420 Iota (ι) Pictoris 420 piggybacking, photography 88 Pillars of Creation 244, 244–45 Pinwheel Galaxy (M101, NGC 5457) 316, 360, 454, 460 Pioneer space probes 105, 116 pions 30, 50 Pisces (the Fishes) 72, 388 Alrescha (Alpha (α) Piscium) 388, 388 Eta (η) Piscium 388 in monthly sky guides 485, 485, 490, 496, 497 PKS 2349 325 Psi-1 (ψ1) Piscium 388 TX Piscium 388, 388 Zeta (ζ) Piscium 388

Piscis Austrinus (the Southern Fish) 404 Beta (β) Piscis Austrini 404 see also Fomalhaut (Alpha (α) Piscis Austrini) Gamma (γ) Piscis Austrini 404 Pistol Nebula 265 Pistol Star 265 Pius Institute, Pope 285 PKS 2349 325 Plancius, Petrus 346, 358, 416 Camelopardalis 358 Columba 408 Monoceros 393 Planck era 48 Planck space telescope 95, 95 Planet X 209 planetary nebulae 25, 255, 256 Ant Nebula 259 Bug Nebula 260–61 Calabash Nebula 262 Cat’s Eye Nebula 258 Crescent Nebula 259 Egg Nebula 258 Eskimo Nebula 259 formation 235–37, 236 Gomez’s Hamburger Nebula 262 Helix Nebula 257 Hourglass Nebula 263 NGC 6751 25 NGC 7662 368, 368, 484 Red Rectangle Nebula 258 Ring Nebula 257 Stingray Nebula 264 Twin Jet Nebula 257 planetesimals 101, 101, 235 planets 12–13, 25, 110–69, 178–207 astrology 64 conjunction 68, 69, 69 Earth 124–35 extra-solar planets 296–99 formation 100, 101, 235, 235 gas giants 103 Jupiter 178–87 Mars 150–69 Mercury 110–13 moons 25 motion 63, 68–69, 68 Neptune 204–207 orbits 102–103 protoplanetary disks 25 rocky planets 103 rotation 39 Saturn 188–99 search for life 57 Solar System 25 space-time 42–43, 42–43 transits 69, 69 Uranus 200–203 Venus 114–23 zodiac 69 planispheres 76, 76 plants 127 Planum Australe (Mars) 163 Planum Boreum (Mars) 161 plasma 30 magnetic fields 251 recreating Big Bang 49 states of matter 30 Sun 106, 107, 107 plasma balls 30 plate tectonics, on Earth 126, 126

Pleiades (NGC 1435) 291, 372, 372 Alcyone (Eta (η) Tauri) 277 Aldebaran 256 binocular astronomy 81 “missing” Pleiad 373 in monthly sky guides 491, 496, 497 Pleione 291, 372 Plough see Big Dipper Plutinos 210 Pluto 209 atmosphere 209 formation of Solar System 101 and Kuiper Belt 209 moons 209, 209 and Neptune 209 orbit and spin 39, 102, 103, 209, 209 structure 209, 209 Pointers 252 polar ring galaxies 305 polar sky charts 348–49 Polaris (Alpha (α) Ursae Minoris) 278–79, 354, 354, 360 circumpolar stars 348 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 448, 454 naked-eye astronomy 77, 77 Pole Star,Vega as 253 see also Polaris (Alpha (α) Ursae Minoris) poles celestial poles 62, 437 magnetic poles 125 pollution, light 76 Pollux (Beta (β) Geminorum) 374 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 436, 437, 443 Polydeuces 190, 195 Pons, Jean Louis 215 Pope, Alexander 202 Population I stars 227 Population II stars 227, 289 populations, stars 227 Porrima (Gamma (γ) Virginis) 253, 378 Portia 201 positrons 31 Big Bang 49 Big Chill 59 emergence of 50 Milky Way 321, 321 potassium, on Mercury 111 Praesepe 290, 375, 436 Praxidike 181 precession 64, 64, 124 pressure Earth’s atmosphere 126 star formation 234 stars 232, 232 prime-focus astrophotography 89 Principle of Equivalence 42, 42 Principle of Relativity 40 prisms, analyzing light 35, 35 Procyon (Alpha (α) Canis Minoris) 284, 392 classification 233 Hertzsprung–Russell (H–R) diagram 232

Procyon cont. in monthly sky guides 436, 497 naked-eye astronomy 77 Winter Triangle 436, 436, 496 Procyon B 232 Promethei Terra (Mars) 163 Prometheus (Io) 184 Prometheus (Saturn’s moon) 190, 191, 192 prominences, Sun 10, 85, 106 propane, on Jupiter 180 proper motion, stars 70 Propus (Eta (η) Geminorum) 284, 374 Prospero 201 Proteus 205, 206 protists 127 protons 28 after Big Bang 50 Big Chill 59 in chemical elements 29 forces 30, 30 proton–proton chain reaction (pp chain) 31, 250 protoplanetary disks 25 protoplanets 101 protostars brown dwarfs 234 evolution to main-sequence stars 232 formation 234, 234–35, 238, 239 protosun 101 Proxima Centauri 22, 232, 252, 398 Psamathe 205 Psi (ψ) Draconis 355 Psi-1 (ψ1) Piscium 388 PSR B1620-26 272 PSR 0531 +21 271, 271 Ptolemy 61, 347 Cetus 389 Corona Australis 415 Delphinus 385 Earth-centered cosmos 63 Equuleus 385 Piscis Austrinus 404 star catalog 346, 421 Puck 201, 202 Pulcherrima (Epsilon (ε) Boötis) see Izar pulsars 267, 267 binary systems 274 Crab Nebula Pulsar 271 Geminga Pulsar 268 PSR B1620-26 272 PSR 0531 +21 271, 271 rotation 39 Vela Pulsar 269, 269 pulsating variable stars 282 Delta (δ) Cephei 286 Eta (η) Aquilae 286 Mira (Omicron (ο) Ceti) 285 Mu (μ) Cephei (Garnet Star) 287 RR Lyrae 286 W Virginis 286 Zeta (ζ) Geminorum (Mekbuda) 286 Puppis (the Stern) 409, 436, 437 b Puppis 409 Calabash Nebula 262 e Puppis 409 k Puppis 409

I N D EX

Pallene 190, 192 Palus Putredinis (Moon) 139 Pan (Amalthea) 182 Pan (Saturn’s moon) 190, 403 Pandora 190, 191 Papin, Denis 396 parabolas, orbits 39 parallax shift 70, 70 Paranal Observatory 90, 209 parhelia 74 Paris Observatory 264 Parsons, William 315, 315, 362, 372 partial eclipses 67 particle-like behavior, electromagnetic (EM) radiation 34 particles in atoms 28 aurorae 74 Big Bang 48–51 Big Chill 59 cosmic rays 24, 228 dark matter 27, 28 electromagnetic (EM) force 30, 30 force-carrier particles 30, 30 and magnetic fields 251 matter 28 neutrinos 27, 27, 32–33 particle accelerators 31, 31, 49 particle physics 31 quantum mechanics 43 radiation 34 radioactive decay 34 solar wind 107, 125 states of matter 30 string theory 31 Sun 106 Pascal, Blaise 148 Pascal Crater (Moon) 148 Pasiphae 181 Pasithee 181 Pavo (the Peacock) 424, 479 Alpha (α) Pavonis 424 Kappa (κ) Pavonis 424 NGC 6782 318 Xi (ξ) Pavonis 424 Pavonis Mons (Mars) 156 Payne-Gaposchkin, Cecilia 233 Peacock see Pavo peculiar (Pec) galaxies 305 Pegasus (the Winged Horse) 386 Alpha (α) Pegasi 386 Beta (β) Pegasi 386 Enif (Epsilon (ε) Pegasi) 386, 478 Fried Egg Galaxy 323 Gamma (γ) Pegasi 386 M15 295, 386, 387, 478, 479 see also Square of Pegasus Stephan’s Quintet 332 Upsilon (υ) Pegasi 386 51 Pegasi 386 Pegasus, in mythology 386 Pele (Io) 185 Pellepoix, Antoine Darquier de 257 Pendulum Clock see Horologium penumbral eclipses 67 Penzias, Arno 51 Perdita 201 Perseid meteor shower 214, 214, 220, 472, 472

521

522

INDEX Puppis cont. L Puppis 409 L2 Puppis 409 M93 290 Naos (Zeta (ζ) Puppis) 409 NGC 2440 nucleus 268 Xi (ξ) Puppis 409 Pwyll Crater (Europa) 183 Pyxis (the Compass) 408 T Pyxidis 408

Q

Quadrans Muralis 363, 430 Quadrantid meteor shower 363, 430 quadruple stars 274 Alcor (80 Ursae Majoris) 276 Alcyone (Eta (η) Tauri) 277 Algol (Beta (β) Persei) 276 Almach (Gamma (γ) Andromedae) 277 Epsilon (ε) Lyrae 276 Mizar (Zeta (ζ) Ursae Majoris) 276 Trapezium (Theta (θ) Orionis) 281 quanta 34 quantum mechanics 43 Quaoar 208 Quark era 48–49 quarks 28, 29, 31 Big Bang 48–50, 49, 50 forces 30 recreating Big Bang 49 quasars 320, 320, 338 BL Lac objects 369 distribution 321 Lyman Alpha (α) lines and forest 338, 338 PKS 2349 325 superluminal jets 321 3C 48 325 3C 273 325, 378 quintuple stars Sigma (σ) Orionis 281

I ND E X

R

R Coronae Borealis 283, 287, 379 R Leporis 407 R Scuti 382 radial velocity extra-solar planets 297 stars 70 radiation Big Bang 22 black holes and 267 cosmic background microwave radiation (CMBR) 36, 51, 54, 334, 337 see also electromagnetic (EM) radiation main-sequence stars 250 red shift and blue shift 35, 35 radiation belts Jupiter 179 Van Allen radiation belts (Earth) 125 radio astronomy 91, 91 radio telescopes 36, 36, 57, 91, 91, 92–93 radio galaxies 320, 320 Centaurus A 322

radio galaxies cont. Cygnus A 324 distribution 321 M87 330–31, 323 NGC 1275 324 NGC 4261 323 Radio Lobe, Milky Way 229 radio waves 34 Milky Way 229, 229 radio window 36 radioactive decay 30, 30, 34 radioactivity 31 Ram see Aries Ramsden, Jesse 175 random walk, radiation 250 Ranger space probes 141, 145 Ras Algethi (Alpha (α) Herculis) 285, 364 ray craters, Moon 139 Rayet, Georges 255, 264, 264 RCW 49 247 RCW 120 238 red dot finders 84, 84 red dwarfs 25 evolution 235 Gliese 229 25 red giants 25, 254 Aldebaran 256 Hertzsprung–Russell (H–R) diagram 232, 232, 255 multiple stars 274 planetary nebulae 255 star life cycles 235–37, 236 TT Cygni 256 red light, photoelectric effect 34, 34 Red Rectangle Nebula (HD 44179) 258 red shift 35, 35 cosmological red shift 35 expanding space 44, 335, 338–39, 339 Lyman Alpha lines and forest 338, 338 mapping the Universe 339, 339 red sprites 75 red supergiant stars 254 Antares (Alpha (α) Scorpii) 256 Betelgeuse (Alpha (α) Orionis) 256 evolution 235 V838 Monocerotis 265 reflecting telescopes 82, 82 reflection nebulae 228, 239 refracting telescopes 82, 82 refraction phenomena 74, 74 Regor (Gamma (γ) Velorum) 233, 253, 410 regular clusters Abell 1689 333 Abell 2065 (Corona Borealis Cluster) 333 Abell 2218 334–35 Coma Cluster 332 Fornax Cluster 329 Hydra Cluster 332 Regulus (Alpha (α) Leonis) 253, 377 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 443 naked-eye astronomy 77 name 72 relativity general theory of relativity 42–43, 51

relativity cont. special theory of relativity 40–41 Renoir region (Mercury) 113 replication, and life 56 residual strong nuclear force 30, 30 Reticulum (The Net) 420 Zeta (ζ) Reticuli 420 retrograde motion 68, 68 Reull Vallis (Mars) 161, 163 Rhea 190, 195 Rheasilvia basin,Vesta 174 Rhea Mons (Venus) 119 Rho (ρ) Cassiopeiae 357 Rho (ρ) Herculis 364 Rho (ρ) Ophiuchi 296, 381, 381 Rho (ρ) Persei 370 rifting, plate tectonics 130 Rigel (Beta (β) Orionis) 281, 390 classification 233, 233 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 431 Right Ascension 63, 63, 77, 87 Rigil Kentaurus see Alpha (α) Centauri Riley, Margaretta 122 Riley Crater (Venus) 122 ring galaxies Hoag’s Object 319 Ring Nebula (M57) 257, 365, 365, 472, 473 Ring of Fire (Earth) 131 rings gravity 38–39 Jupiter 181, 181 Neptune 205, 205 Saturn 13, 38–39, 188, 191, 191 Uranus 201, 201 River see Eridanus rivers, on Earth 134, 134 rocks Earth 124 Mars 167, 167 Moon 138, 138, 146, 147 rocky planets 103 Romans, constellations 346 Romulus and Remus Crater (Dione) 195 Rosalind 201 Rosetta space probe 172, 217, 218 Rosette Nebula 393, 393, 436 Rotanev (Beta (β) Delphini) 385 rotating variable stars Procyon (Alpha (α) Canis Minoris) 284 rotation angular momentum 39, 39 neutron stars 267, 267 spiral galaxies 302 stars 251 synchronous rotation 136 Rotten Egg Nebula 262 Royal Stars 256 RR Lyrae 286 RS Ophiuchi 287 Ruapehu, Mount (Earth) 131 Rupes Altai (Moon) 145 Russell, Henry 232 RX J1856.5-3754 268

S

S Monocerotis 242, 393 S Sagittae 382 S/2003 J2 181 S/2003 J3 181 S/2003 J4 181 S/2003 J5 181 S/2003 J9 180 S/2003 J10 181 S/2003 J12 181 S/2003 J15 181 S/2003 J16 181 S/2003 J18 181 S/2003 J19 180 S/2003 J23 181 S/2003 S1 191 S/2004 S7 191 S/2004 S12 191 S/2004 S13 191 S/2004 S17 191 S/2006 S1 191 S/2006 S3 191 S/2007 S2 191 S/2007 S3 191 S/2009 S1 191 S/2010 J1 181 S/2010 J2 181 S/2011 P1 (P4) 209 Sacajawea Patera (Venus) 119 Sachs Patera (Venus) 119 SagDEG (Sagittarius Dwarf Elliptical Galaxy) 310, 328 Sagitta (the Arrow) 382 S Sagittae 382 WZ Sagittae 382 Zeta (ζ) Sagittae 382 Sagittarius (the Archer) 400–401 Beta (β) Sagittarii 400 Epsilon (ε) Sagittarii 400 Gomez’s Hamburger Nebula 262 Lagoon Nebula 243 MACHO 96 273 in monthly sky guides 455, 461, 466, 467, 472, 473 Pistol Star 265 Teapot 400, 467, 473 Trifid Nebula 246 WR 104 259 WR 124 264 9 Sagittarii 400 Sagittarius A 229, 400 Sagittarius A* 229, 229, 400, 467 Sagittarius A West 229, 229 Sagittarius Arm, Milky Way 227 Sails see Vela salts 29, 29 Sandage, Allan 325 Sao 205 Sapas Mons (Venus) 120 Saskia Crater (Venus) 123 satellites 75 see also individual named satellites and space probes Saturn 89, 188–99, 198–99 atmosphere 189, 189 formation of Solar System 101 moons 190, 190–91, 192–97 orbit and spin 103, 188, 188 rings 13, 38–39, 188, 191, 191 space probes 196, 196 structure 188, 188 weather 190, 190 Saturn Nebula (NGC 7009) 255, 387, 387, 479

Scales see Libra Scattered Disk 208, 211 Objects 210, 210 Schiaparelli, Giovanni 164, 214, 220 Schiaparelli Crater (Mars) 164 Schmidt–Cassegrain telescopes 84, 84 Schmitt, Harrison “Jack” 146, 146 Scooter (Neptune) 205 Scorpion see Scorpius Scorpius (the Scorpion) 402 see also Antares (Alpha (α) Scorpii) Beta (β) Scorpii 402 BM Scorpii 290, 402 Bug Nebula 260–61 Butterfly Cluster 290 Delta (δ) Scorpii 402 GRO J1655-40 272 M4 294 Mu (μ) Scorpii 402 in monthly sky guides 455, 461, 466, 467, 472, 473 Nu (ν) Scorpii 402 Omega (ω) Scorpii 402 PSR B1620-26 272 Scorpius X-1 402 Xi (ξ) Scorpii 402 Zeta (ζ) Scorpii 402, 461 Scorpius–Centaurus Association 229, 229 Sculptor 404 Cartwheel Galaxy 319 Epsilon (ε) Sculptoris 404 Sculptor Group 329, 336 Scutum (the Shield) 382, 472 Delta (δ) Scuti 382 R Scuti 382 Wild Duck Cluster 382, 382, 472, 473 Scutum Star Cloud 382 SDO, Solar Dynamics Observatory 105, 219 SDOs, Scattered Disk Objects 210, 210 Sea Goat see Capricornus Sea Monster see Cetus Sea of Tranquillity (Moon) 144 seas, on Earth 135 seasons Earth 65, 65, 124 Mars 150, 150 Neptune 204 Uranus 200 Secchi, Father Angelo 285 Sedan Crater (Nevada Desert) 148 Sedna 211 seeing, telescopes 85 segmented mirrors 91 Seki Tsutomu 214 September sky guide 478–83 Serpens (the Serpent) 380, 460, 466 Delta (δ) Serpentis 380 Eagle Nebula 244–45 Hoag’s Object 319 Seyfert’s Sextet 308, 329 Theta (θ) Serpentis 380 Unukalhai (Alpha (α) Serpentis) 380 Serpens Cauda 467 Serpent see Serpens Set Square see Norma Setebos 201

INDEX Sirrah 368 Sk-69 202 265 Skathi 191 Skoll 191 sky guides 426–501 Slipher,Vesto 316, 316 Sloan Digital Sky Survey 338–39 Small Magellanic Cloud (SMC, NGC 292) 294, 302, 305, 311, 418, 418 Milky Way halo 229 in monthly sky guides 431, 473, 479, 479, 485, 490, 491, 497 SMART-1 spacecraft 139, 141 SN 437 (Geminga Pulsar) 268 SN 1572 (Tycho’s Supernova) 272 SN 1604 (Kepler’s Star) 37, 273, 381 SN 1680 (Cassiopeia A) 55, 273 SN 1987A 265 Snowman craters,Vesta 174 sodium, on Mercury 111, 111 sodium chloride 29 software, image processing 89 SOHO solar observatory 104–105, 105, 106, 107, 219 Soho-6, Comet 213 Sojourner 152, 152 solar day 66, 66 Solar Dynamics Observatory 105, 219 solar eclipses 67, 67 solar flares 10, 98–99, 106, 250 Solar Maximum Mission 105 solar nebulae, formation of Solar System 100 solar quakes 106 solar telescopes 85, 85 Solar System 25, 98–223 asteroids 170–77 comets 212–19 Earth 124–35 history 100–101 Jupiter 178–87 Kuiper Belt 208–10 life, search for 57 Mars 150–69 Mercury 110–13 meteors and meteorites 220–23 in Milky Way 229 Moon 136–49 Neptune 204–207 Oort Cloud 208–11 orbits 39, 102–103 planets 12–13 Pluto 209 Saturn 188–89 size 22 Sun 104–109 Uranus 200–203 Venus 114–23 solar systems, formation 235, 235 Solar Terrestrial Relations Observatory (STEREO) 105 solar wind 10, 107 aurorae 74 bow shock 125 charged particles 125 Jupiter 179 solids, states of matter 30 Solis Planum (Mars) 160

solstices 65, 65, 124, 460 Sombrero Galaxy (M104, NGC 4594) 316, 378, 378 SOPHIE 297 south celestial pole 62, 437 South Polar Group 329 South Polar Region (Mars) 163 South Polar sky 349 South Pole, AASTO project 305 South Pole-Aitken Basin Crater (Moon) 140, 149 Southern Cross see Crux Southern Crown see Corona Australis Southern Fish see Piscis Austrinus Southern Pinwheel (M83) 302, 394, 394, 455, 461 Southern Pleiades (IC 2602) 411, 443, 449 space Big Bang 48–51 expanding 44–45, 58, 338–39, 339 space and time 40–43, 59 see also Universe space observatories 94–95 space probes see also individual named probes and satellites Mars 152, 159 Moon 139, 141 Saturn 196, 196 Sun 105, 105 Venus 116 Space Shuttle 8 special theory of relativity 40–41 spectra 35, 35 identifying binary stars 274 spectroscopy 35, 35 star classification 233 Wolf–Rayet stars 255 spectrographs 297, 339 spectroscopic binaries 274 speed of light 34, 40, 41 Spencer, Dr L.J. 223 Spica (Alpha (α) Virginis) 378 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 442, 443, 448, 449, 454, 455, 460, 461, 466, 467 naked-eye astronomy 77 spicules, Sun 106, 107 spin Earth 124, 124 Jupiter 178, 178 Mars 150, 150 Mercury 110, 110 Moon 136, 136 Neptune 204, 204 Pluto 209 Saturn 188, 188 Uranus 200, 200 Venus 114, 114 Spindle Galaxy (M102, NGC 3115) 317, 396, 396 spiral galaxies 26, 302–303 Andromeda Galaxy (M31, NGC 224) 312–13 Antennae Galaxies 317 barred spiral galaxies 26, 302 Black Eye Galaxy 314 Bode’s Galaxy 314 Cartwheel Galaxy 319 classification 302, 302

spiral glaxies cont. density waves 227, 239, 303 ESO 510-G13 318 galaxy clusters 327 the Mice 318 Milky Way 226–29 NGC 6782 318 Pinwheel Galaxy 316 Sombrero Galaxy 316 Triangulum Galaxy 311 Whirlpool Galaxy 315 Spitzer Space Telescope 26, 36, 55, 230, 247, 247, 297, 298 Splinter Galaxy 308 Sponde 181 spring equinox 65, 65, 124 Square of Pegasus 72, 368, 386 in monthly sky guides 430, 466, 472, 473, 478, 479, 484, 484, 485, 490, 491, 496, 497 SS 433 26 star clusters Beehive Cluster 290 Butterfly Cluster 290 catalogs 73 Christmas Tree Cluster 242 evolution 289, 289 Hyades 290 Jewel Box (Kappa (κ) Crucis) 294 M4 294 M9 292–93 M12 295 M14 295 M15 295 M52 290 M68 295 M93 290 M107 295 moving clusters 360 NGC 3201 294 NGC 4833 295 Omega Centauri 294 open clusters 288, 290 Pleiades 291 Trapezium 241, 241, 281 47 Tucanae 294 starburst galaxies 305, 309, 314 Stardust mission 172, 217, 218 Stardust–NExT 218 starquakes 267 stars 14–15, 232–95 accretion disks 244, 247 apparent magnitude 233 Arabic names 346 asterisms 72 Big Chill 59 binary stars 25, 274, 276 brightness 71 brown dwarfs 25, 25 carbon stars 256, 256 catalogs 72, 346 celestial coordinates 63, 63 celestial sphere 62–63 Cepheid variable stars 44, 311, 313 charts and atlases 347 classification 233 collapsing 237, 266 colors 70–71 death 25 evolution 235–37 first stars 55 formation 25, 232, 234, 238–47 giant stars 25

stars cont. Hertzsprung–Russell (H–R) diagram 232, 232 hypernovae 37, 55 interstellar medium 228 life cycles 232, 234–37 light 25 luminosity 232, 232, 233 magnetic fields 251 main-sequence stars 250–53 mapping the sky 348–53 mass 232 Milky Way 226–29 molecular clouds 228 motion and patterns 70–73 multiple stars 274–81 names 72 neutron stars 25 nuclear fusion 31, 31 old stars 254–65 planet formation 235, 235 plasma 30 populations 227 red dwarfs 25, 25 rotation 39, 251 sidereal day 66, 66 space-time 43 spectroscopy 35, 35 stellar end points 266–73 structure 250 Sun 104–107 supergiants 25, 25 temperature 232, 232 variable stars 262, 282–87 white dwarfs 25, 25 Wolf–Rayet stars 247, 255, 256, 264 see also constellations; galaxies; star clusters and individual named stars star parties 85 star trails 88 states of matter 30 Stein Crater Field (Venus) 123 Steins 172 stellar black holes 26, 26 stellar end points 266–73 stellar nurseries 238 stellar winds 238, 239 Stephano 201 Stephan’s Quintet (Hickson 92) 332 STEREO satellite 105 Stern see Puppis Stingray Nebula (Hen-1357) 264 stony-iron meteorites 170, 220 stony meteorites 220 storms Jupiter 181, 181 Mars 151, 151, 159 Neptune 205 Saturn 190, 190 stratosphere, Earth’s atmosphere 126 string theory 31, 31, 43 stromatolites 56 strong nuclear force 30, 30, 48 Struve, F. 277 Struve 747 391 Struve 2725 385 Sualocin (Alpha (α) Delphini) 385 subatomic particles see particles al-Sufi 312, 346, 421, 421 sulphur, properties 29 sulphuric acid, on Venus 115 Sumerians, constellations 346 summer solstice 65, 65, 124

I N D EX

SETI (search for extraterrestrial intelligence) 57 setting up telescopes 86–87 Seven Sisters see Pleiades Sextans (the Sextant) 396 sky guide 442 17 Sextantis 396 18 Sextantis 396 Sextant see Sextans sextuple systems Castor 276 Seyfert, Carl 323, 324 Seyfert galaxies 315, 320, 320 Circinus Galaxy 322 distribution 321 Fried Egg Galaxy 323 M77 389, 389, 491 NGC 1275 324 NGC 5548 323 Seyfert’s Sextet (NGC 6027 and NGC 6027A-C) 308, 329 Shackleton, Ernest 166 Shakespeare, William 202, 203 Shakespeare region (Mercury) 113 Shapley Supercluster 336 sheets, galaxy superclusters 338 Sheliak (Beta (β) Lyrae) 281, 365 shepherd moons, Saturn 191 Sher 25 265 Shergotty meteorite 157 Shield see Scutum Shoemaker, Carolyn 217, 217 Shoemaker, Eugène (Gene) 139, 139, 217 Shoemaker–Levy 9, Comet 181, 181, 217 shooting stars 75, 220 short-period comets 212 Shorty Crater (Moon) 146, 147 Siarnaq 191 Sickle 377 sidereal day 66, 66 sidereal month 66, 69 Sif Mons (Venus) 119 Sigma (σ) Coronae Borealis 379 Sigma (σ) Octantis 425 Sigma (σ) Orionis 240, 281, 390, 391 Sigma (σ) Tauri 372 silicaceous (S-type) asteroids 170 silicates dust 24 interstellar medium 228 silicon, formation of 55 singularity, black holes 26, 43 Sinope 181 Sinus Iridum (Moon) 139 Sippar Sulcus (Ganymede) 186 Sirius A (Alpha (α) Canis Majoris) 252, 392 apparent magnitude 71 binary system 274 classification 233 Hertzsprung–Russell (H–R) diagram 232 in monthly sky guides 430, 431, 437, 442, 443, 491, 497 naked-eye astronomy 77 name 72 Winter Triangle 436, 436, 496 Sirius B (HD 48915 B) 268, 392 binary system 274 Hertzsprung–Russell (H–R) diagram 232 as white dwarf 266

523

I ND E X

524

INDEX Summer Triangle 460, 466, 466, 472, 473, 478, 479, 484, 490, 497 see also Altair (Alpha (α) Aquilae); Deneb (Alpha (α) Cygni) naked-eye astronomy 77 see also Vega (Alpha (α) Lyrae) Sun 10–11, 104–109, 108–109 analemma 64 angular diameter 77 astrology 64 atmosphere 107, 107 celestial cycle 64 classification 233, 233 comets 213 corona 10, 67 eclipses 67 faculae 85, 106, 108–109 formation of Solar System 100, 101 helium production 250 Hertzsprung–Russell (H–R) diagram 232 ice haloes 74 internal structure 104 luminosity 233 as main-sequence star 251 magnetic field 108–109 midnight Sun 64–65 in Milky Way 229, 229 movements across sky 63 nuclear fusion 31 photosphere 104, 106, 106, 107 plasma loops 106 prominences 10, 85 solar day 66, 66 solar flares 10, 98–99, 106, 250 Solar System 25 solar telescopes 85, 85 space probes 105, 105 space-time 42–43 sunspots 10–11, 85, 106, 106, 108–109, 251 surface 106, 106 temperature 106, 107 transits by planets 69, 69, 110 zodiac 64, 65 sun dogs 74 Sunflower Galaxy (M63) 362, 362 sunlight noctilucent clouds 75, 75 zodiacal light 75, 75 sunspots 108–109 suns see stars Sunyaev–Zel’dovich effect 334, 335 La Superba (Gamma (γ) Canum Venaticorum) 362 superclusters see galaxy superclusters supergiants 25, 254 Antares (Alpha (α) Scorpii) 256 Betelgeuse (Alpha (α) Orionis) 256 Eta (η) Carinae 248–49, 262 evolution 235 Hertzsprung–Russell (H–R) diagram 232, 232, 255 Sher 25 265 star life cycles 235, 235–37, 236 stellar black holes 26 V838 Monocerotis 265

Superior, Lake (Earth) 134, 134 superior planets, motion 68, 68 superluminal jets 321, 321 supermassive black holes 26, 26, 59, 305, 305, 307 Supernova 1987A 266, 310, 421 Supernova 1994D 283 supernova remnants 25, 25 Crab Nebula 270–71 Cygnus Loop 269 Vela Supernova 269 supernovae 25, 254 and black holes 267 Cassiopeia A 273 dark energy 58, 58, 339 expansion of Universe 339 formation of 236, 237 formation of elements in 236 Kepler’s Star 273 life cycles of stars 234 and meteorites 222 and neutron stars 267 radiation 36 star evolution 235, 235 star formation 238, 239, 239 Tycho’s Supernova 272 Type I supernovae 283 Type II supernovae 266, 267 Surtsey (Earth) 130 Surtur 191 Surveyor space probes 141 Suttungr 191 Suzaku observatory 95 Swan see Cygnus Swift, Lewis 214 Swift–Tuttle, Comet 212, 214, 220 Sycorax 201, 203 synchronous rotation 136 synchrotron mechanism 320, 320

T

T Coronae Borealis (Blaze Star) 286 T Pyxidis 408 T Tauri 239 Table Mountain see Mensa Tadpole 27, 309 Tagish Lake meteorite 222 tails, comets 212, 213, 213 Tarantula Nebula (30 Doradus) 311, 421 brightness 310, 310 in monthly sky guides 431, 437, 443, 491, 497 Tarazed (Gamma (γ) Aquilae) 383, 383 Tarqeq 191 Tarvos 191 Tau (τ) Canis Majoris 392, 392 Tau (τ) Ceti 232, 389 Taurid meteor shower 372, 490 Taurus (the Bull) 372–73 Alcyone (Eta (η) Tauri) 277, 291, 372 see also Aldebaran (Alpha (α) Tauri) Alnath (Beta (β) Tauri) 232, 359, 372 Crab Nebula 270–71 Hyades 290 Lambda (λ) Tauri 284, 372 in monthly sky guides 436, 437, 442, 496, 497 Pleiades 291

Taurus cont. Sigma (σ) Tauri 372 T Tauri 239 Theta (θ) Tauri 372 Zeta (ζ) Tauri 372 Taurus-Littrow Valley (Moon) 146–47 Taygeta 291 Taygete 181 Teapot 400, 467, 473 tectonic features Earth 126, 130–33 Mars 152, 156–60 Venus 116, 116, 118–21 tektite 221 Telescope see Telescopium telescopes 82–87, 347 astrophotography 88–89 catadiotropic 82, 82, 83 computerized 84, 84, 87, 87 early astronomy 82, 82 Galileo’s 82 Hubble Space Telescope 45, 94, 94, 230, 297, 337 infrared astronomy 36, 36, 95 Newton’s 82 observatories 90–93 optical telescopes 37, 37 planet-hunting 299 radio astronomy 36, 36, 92–93 reflecting telescopes 82, 82 refracting telescopes 82, 82 setting up 86–87 Spitzer telescope 230, 247, 247 solar telescopes 85, 85 Telescopium (the Telescope) 416 Delta (δ) Telescopii 416 Telesto 190, 194 Tempel, Wilhelm 218 Tempel–Tuttle, Comet 212, 220 Tempel 1, Comet 218 temperature Big Bang 48, 51, 54 gas giants 298 Hertzsprung–Russell (H–R) diagram 232, 232 interstellar medium 228 on Io 184 Jupiter 178, 181 main-sequence stars 250, 251 Mars 150, 151 Mercury 110, 111 Moon 137 old stars 255 Pluto 209 red giants 254 Saturn 189 star classification 233 star formation 234, 238 Sun 106, 107 Uranus 201 Venus 115 Terra satellite 129 Tethys 190, 192, 194, 195 Teviot Vallis (Mars) 163 Thackeray, A.D. 246 Thalassa 205 Tharsis Bulge (Mars) 152, 155, 156, 158, 160 Thebe 180, 181, 182 Theia Mons (Venus) 119 Thelxinoe 181 Themisto 180, 182 thermosphere, Earth’s atmosphere 126

Theta (θ) Apodis 423 Theta (θ) Carinae 411, 443 Theta (θ) Eridani 406 Theta (θ) Indi 416 Theta (θ) Muscae 413 Theta (θ) Orionis (Trapezium) 241, 241, 275, 276, 281, 391, 391 Theta (θ) Serpentis 380 Theta (θ) Tauri 372 Thor’s Helmet 264 Thymr 191 Thyone 181 Tibetan Plateau (Earth) 132, 133 tidal forces, and galaxies 309 tides, and gravity 138, 138 Tigre River (Earth) 134 time and space 40–43 Big Bang 48 celestial cycles 64, 66 expanding space 45, 339, 339 lunar month 66 sidereal day 66, 66 sidereal month 66 solar day 66, 66 space-time 41, 41, 42–43, 42–43, 59 time dilation 41, 41 Titan 57, 190, 190, 196 Titania 201, 203 titanium, on Moon 144 Titanomachia 415 Titans, in mythology 415 Tohil Mons (Io) 184 Tombaugh, Clyde 209 total eclipses 67, 67 Toucan see Tucana Toutatis 172 Tr37 star cluster 243 TRACE satellite 105, 107 transit method 297 transition region, Sun 107 transits, planets 69, 69, 110 transverse velocity, stars 70 Trapezium (Theta (θ) Orionis) 241, 241, 275, 276, 281, 391, 391 Triangulum (the Triangle) 369 Local Group 328 3C 48 325 6 Trianguli 369 Triangulum Australe (the Southern Triangle) 414, 461 Alpha (α) Triangulum Australis 414 Triangulum Galaxy (M33, NGC 598) 302, 311, 328, 369, 369, 485, 491 Trifid Nebula (M20) 246, 400, 400, 467 Trinculo 201 triple stars Albireo (Beta (β) Cygni) 277 Beta (β) Monocerotis 281 Omicron (ο) Eridani 276 Rigel (Beta (β) Orionis) 281 Triton 205, 205, 206–207, 209 Trojan asteroids 170, 170–71 Tropic of Cancer 65 Tropic of Capricorn 65 troposphere, Earth’s atmosphere 126, 126 Trumpler 14 247 Trumpler 16 247 Tsiolkovsky, Konstantin 148 Tsiolkovsky Crater (Moon) 148 TT Cygni 256

Tucana (the Toucan) 418, 479 Beta (β) Tucanae 418 Kappa (κ) Tucanae 418 see also Small Magellanic Cloud (SMC) 47 Tucanae 294, 311, 418, 418, 479, 485, 491 Tuttle, Horace 214 TWA 5A, 5B 298 Twin Jet Nebula (M2-9) 257 Twins see Gemini Two-degree-Field Galaxy Redshift Survey, 2dFGRS 339 Two–micron All Sky Survey (2MASS) 340–41 Tycho catalog 70 Tycho Crater (Moon) 139, 140, 145, 147 Tycho’s Supernova (SN 1572) 272 Type I supernovae 283 Type II supernovae 266, 267

U

U Geminorum 284 UFOs (unidentified flying objects) 75, 75 UKIDSS (UKIRT) survey 336 ultraviolet radiation 34, 37, 260 first stars 55 galaxies 305 observatories 37, 37 photoelectric effect 34 Ulysses space probe 105, 215 Umbriel 201, 203 Unicorn see Monoceros United Kingdom Infrared Telescope (UKIRT) 36, 91 Universe age 44, 337, 338 Big Bang 22, 48–51 constituent parts 24–25 dark ages 54 early models of 63, 63 expanding space 44–45, 58, 335, 339, 339 fate of 58–59 general theory of relativity 43, 51 geometry of 59 life in 56–57 mapping 339, 340–41, 348–49 matter 28–31 observable Universe 23 radiation 34–37 scale of 22–23 space and time 40–43 Unukalhai (Alpha (α) Serpentis) 380 Upsilon (υ) Andromedae A exoplanets 298, 298, 299 Upsilon (υ) Pegasi 386 Uranus 200–203 atmosphere and weather 201, 201 moons 201, 202–203 orbit and spin 102, 200, 200 rings 201, 201 structure 200, 200 Ursa Major (the Great Bear) 360–61, 448 Alcor (80 Ursae Majoris) 276, 360, 361, 454

INDEX Ursa Major cont. Alioth (Epsilon (ε) Ursae Majoris) 72, 360 Alkaid (Eta (η) Ursae Majoris) 72, 360 Bode’s Galaxy 314, 360, 360 Cigar Galaxy 305, 314, 360 Delta (δ) Ursae Majoris 360 see also Dubhe (Alpha (α) Ursae Majoris) Merak (Beta (β) Ursae Majoris) 72, 77, 360 Mizar (Zeta (ζ) Ursae Majoris) 72, 276, 360, 361, 454 naked-eye astronomy 77, 77 Phad (Gamma (γ) Ursae Majoris) 72, 360 Pinwheel Galaxy 316, 360, 454, 460 star chart 72–73 Xi (ξ) Ursae Majoris 360 Ursa Minor (the Little Bear) 354 Abell 2125 333 Eta (η) Ursae Minoris 354 Gamma (γ) Ursae Minoris 354 see also Polaris (Alpha (α) Ursae Minoris) 11 Ursae Minoris 354 19 Ursae Minoris 354 Utopia Planitia (Mars) 162 UW Canis Majoris 392

V

Volans (the Flying Fish) 422 Epsilon (ε) Volantis 422 Gamma (γ) Volantis 422 volcanoes Earth 126, 130, 130, 131, 131 Io 184, 184–85 Mars 152, 156–57, 156–57, 160, 160 Moon 137 Venus 116, 116, 119, 119, 120, 120 Volga Delta (δ) (Earth) 135 von Kármán vortex streets 128–29 Voyager space probes Neptune 204 Uranus 200 Vulcan 110 Vulpecula (the Fox) 384, 472 Alpha (α) Vulpeculae 384 Dumbbell Nebula 89, 384, 384, 472, 473

W

W Virginis 286 walls, galactic 338 Wanda Crater (Venus) 122 water atomic structure 29 Earth 125, 126, 127, 127 extra-solar planets 299 features formed on Earth 134–35 features formed on Mars 161–63 interstellar medium 228 Jupiter 180 and life 56 Mars 153, 153 the Moon 149 Neptune 204 Pluto 209 Saturn 189 Saturn’s rings 191 states of matter 30 Uranus 200, 201 Water Carrier see Aquarius Water Jar 387 Water Snake see Hydra wave-like behavior, electromagnetic (EM) radiation 34, 34 wavelengths analyzing light 35, 35 celestial objects 36 electromagnetic (EM) radiation 34 galaxies 305 luminosity 233 photons 34 red shift and blue shift 35, 35 WC stars 255 weak interaction, Big Bang 49 weak nuclear force 30, 30 weather Earth 126, 126 Jupiter 181, 181 Mars 151 Neptune 205 Saturn 190, 190 Uranus 201 webcams 89, 89 weight and gravity 38 weightlessness 38, 38 Weinberg, Steven 30

werewolves 138, 138 West, Comet 215, 219 West, Richard 215 Whipple, Fred 213, 213 Whirlpool Galaxy (M51, NGC 5194, NGC 5195) 14, 302, 315, 362, 362, 454, 460 white dwarfs 25, 25, 266 Big Chill 59 classification 233 Hertzsprung–Russell (H–R) diagram 232, 232 multiple stars 274 NGC 2440 nucleus 268 novae 282 planetary nebulae 255 Sirius B 268, 274, 392, 437, 443, 491 space-time 43 star life cycles 235, 235, 236, 237 Type I supernovae 283, 283 white stars Altair (Alpha (α) Aquilae) 252 Fomalhaut (Alpha (α) Piscis Austrini) 253 Sirius A (Alpha (α) Canis Majoris) 252 Vega (Alpha (α) Lyrae) 253 Wild 2, Comet 172, 217, 218 Wild Duck Cluster (M11) 382, 382, 472, 473 Wilkinson Microwave Anisotropy Probe (WMAP) 36, 36, 95, 337 William the Conqueror, King of England 216 Wilson, Robert 51 WIMPs (weakly interacting massive particles) 27, 28 wind erosion Mars 164, 164 Venus 117 winds Jupiter 181 Mars 151, 151 Saturn 190 stellar winds 238, 239 Winged Horse see Pegasus winter solstice 65, 65, 124 Winter Triangle in monthly sky guides 430, 436, 436, 496 naked-eye astronomy 77, 77 Wirtanen, Comet 217 WN stars 247, 255 WO stars 255 Wolf see Lupus Wolf, Charles 255, 264 Wolf, Max 173 Wolf–Rayet stars 247, 255, 256, 264 HD 56925 264 Regor (Gamma (γ) Velorum) 253 WR 104 259 WR 124 264 Wunda Crater (Umbriel) 203, 203 WZ Sagittae 382

X-rays cont. gravitational lensing 335 intergalactic medium 327 observatories 37, 37, 95 Sunyaev–Zel’dovich effect 334 supermassive black holes 305 Xanadu (Titan) 196 Xi (ξ) Boötis 363 Xi (ξ) Lupi 399 Xi (ξ) Pavonis 424 Xi (ξ) Puppis 409 Xi (ξ) Scorpii 402 Xi (ξ) Ursae Majoris 360 XMM–Newton X–ray Space Telescope 95

Y

yellow stars Alpha (α) Centauri (Rigil Kentaurus) 252 yellow-white stars Porrima 253, 378 Yerkes Observatory, Telescope 90 Ymir 191 Yohkoh space probe 105, 105

Z

Zach, Franz Xaver von 171 Zeta (ζ) Antliae 396 Zeta (ζ) Aquarii 387 Zeta (ζ) Aurigae 359 Zeta (ζ) Boötis 277 Zeta (ζ) Canceri 375 Zeta (ζ) Cepheus 356 Zeta (ζ) Coronae Borealis 379 Zeta (ζ) Geminorum (Mekbuda) 286, 374 Zeta (ζ) Herculis 364 Zeta (ζ) Leonis 377 Zeta (ζ) Lyrae 365 Zeta (ζ) Ophiuchi 268 Zeta (ζ) Orionis (Alnitak) 232, 390, 391, 391 Zeta (ζ) Phoenicis 417 Zeta (ζ) Piscium 388 Zeta (ζ) Puppis (Naos) 409 Zeta (ζ) Reticuli 420 Zeta (ζ) Sagittae 382 Zeta (ζ) Scorpii 402, 461 Zeta (ζ) Ursae Majoris (Mizar) 72, 276, 360, 361, 454 Zeus 354, 354, 361, 367, 415 zodiac 65, 69 astrology 64 Islamic 64 zodiacal light 75, 75 Zubenelgenubi (Alpha (α) Librae) 379 Zubeneschamali (Beta (β) Librae) 379 ZZ Ceti 232

X

X-bosons 49 X-rays 34 black holes 267, 320 galaxy clusters 329, 329

I N D EX

V* V1033 Sco 272 V647 Tau (τ) 277 V838 Monocerotis 265, 282–83 Valhalla Basin (Callisto) 187, 187 Valles Marineris (Mars) 151, 152, 152, 154–55, 158–59 Van Allen, James 125 Van Allen radiation belts (Earth) 125 Van De Graaff Crater (Moon) 148 variable stars 262, 282–87 bizarre variables 283 Cepheid variable stars 44, 282, 282, 286, 311, 313 Delta (δ) Cephei 286 Eta (η) Aquilae 286 Gamma (γ) Cassiopeiae 285 Mira (Omicron (ο) Ceti) 285 Mu (μ) Cephei (Garnet Star) 287 Pistol Star 265 Procyon (Alpha (α) Canis Minoris) 284 pulsating variable stars 282 R Coronae Borealis 287 RR Lyrae 286 U Geminorum 284 W Virginis 286 Zeta (ζ) Geminorum (Mekbuda) 286 Vatican Observatory 285 Vega (Alpha (α) Lyrae) 253, 365, 366 circumstellar disk 296 Hertzsprung–Russell (H–R) diagram 232 luminosity 233

Vega cont. in monthly sky guides 448, 454, 460, 461, 466, 467, 472, 473, 478, 479 naked-eye astronomy 77 Veil Nebula 25, 269, 367 Vela (the Sails) 410, 436, 437 Delta (δ) Velorum 410 Kappa (κ) Velorum 410 Lambda (λ) Velorum 410 NGC 3201 294 Omicron (ο) Velorum 410 Regor (Gamma (γ) Velorum) 233, 253, 410 Vela Pulsar 269, 269 Vela Supernova (NGC 2736) 269, 410 velocity light 34, 40, 41 motion of stars 70 Venera space probes 116, 117 Venus 114–23 atmosphere 115, 115 formation of Solar System 101 impact craters 117, 117, 122–23 maps 116–17, 117 motion 68, 68 occultations 69 orbit and spin 102, 114, 114 phases 68 space probes 116 structure 114, 114 tectonic features 116, 116, 118–21 transits 69, 69 Venus Express 116, 116 vernal equinox 65, 65, 124, 371, 388 Very Large Array, New Mexico 36, 36 Very Large Telescope 55, 90, 91, 321 Vespucci, Amerigo 412, 412 Vesta 170, 174 vibrations, string theory 31 Victoria Crater (Mars) 164 Viking space probes 152 Virgin see Virgo Virgo (the Virgin) 378, 454 Abell 1689 333 M60 317 M87 304, 330–31, 323, 329, 378, 378 NGC 4261 323 Porrima (Gamma (γ) Virginis) 253, 378 Sombrero Galaxy 316, 378, 378 see also Spica (Alpha (α) Virginis) W Virginis 286 3C 273 325 Virgo A 330–31 see also M87 Virgo Cluster 23, 27, 329, 340–41, 376, 378 central region 327 dark galaxies 326 galaxy superclusters 336, 336 in monthly sky guides 448, 449, 454 Virgo Supercluster 336 viruses 56, 56 visual binaries 274 VLT (Very Large Telescope) 55, 90, 91 voids, superclusters 338–39

525

526

ACKNOWLEDGMENTS

ACKNOWLEDGMENTS Dorling Kindersley would like to thank the following people for their help in the preparation of this book: Anne Brumfitt and her colleagues at the European Space Agency for editorial advice; Stephen Hawking for permission to reproduce the quotation on p.21; Giles Sparrow for advice on the contents list; Gillian Tester and Andrew Pache for DTP support; Dave Ball, Sunita Gahir, and Marilou Prokopiou for additonal artwork; Malcolm Godwin of Moonrunner Design; Rajeev Doshi of Combustion Design and Advertising; Philip Eales and Kevin Tildsley of Planetary Visions;Tim Brown and Giles Sparrow of Pikaia Imaging;Tim Loughhead of Precision Illustration; John Plumer of JP Map Graphics; Richard Tibbitts of Antbits; and Greg Whyte of Fanatic Design. For their help in preparing the revised edition, Dorling Kindersley would like to thank: Ian Ridpath for planning the updates and providing most of the new text; Robin Scagell, Giles Sparrow, and Robert Dinwiddie for additional text; Carole Stott for advice on picture selection, as well as additional text; Professor Derek Ward-Thompson for helping to plan the sections on galaxy evolution and galaxy superclusters and for his comments on the text; Professor Carlos Frenk and Rob Crain for their images of simulations of galaxy formation; Andy Lawrence for providing an original image from the UKIDSS project; Lili Bryant and Laura Wheadon for editorial assistance; Natasha Rees for design assistance; Mik Gates for new illustrations; and Anita Kakar, Rupa Rao, Priyaneet Singh, Alka Ranjan, Ivy Roy, Bimlesh Tiwary, Tanveer Zaidi, Tarun Sharma, and Pushpak Tyagi at DK Delhi. Smithsonian Enterprises Carol LeBlanc, Vice President; Brigid Ferraro, Director of Licensing; Ellen Nanney, Licensing Manager; and Kealy Wilson, Product Development Coordinator. PICTURE CREDITS Dorling Kindersley would like to thank the following for their help in supplying images: Till Credner; Robin Scagell at Galaxy Picture Library; Romaine Werblow in the DK Picture Library; Anna Bond at Science Photo Library.

SIDEBAR IMAGES

© CERN Geneva (Introduction); SOHO (The Solar System); NASA: HST/ESA, HEIC and HHT (STScI/ AURA) (Milky Way); HST/HHT (STScI/AURA) (Beyond our Galaxy); SPL: Kaj R. Svensson (The Night Sky).

1 NASA: JPL-Caltech/K. Su (University of Arizona). 2–3 Processed image © Ted Stryk: Raw data courtesy NASA/JPL. 4 Corbis: Roger Ressmeyer (tc). 5 NASA: JPL (tr); JPL/STScI (cla); NOAO: T.A. Rector (NRAO/AVI/ NSF and NOAO) and B.A.Wolpa (NOAO) (b). 6–7 NOAO: Adam Block (background). 8 Corbis: Digital Image © 1996 Corbis; Original image courtesy of NASA, 9 Corbis: (ca); Landsat 7 satellite

image courtesy of NASA Landsat Project Science Office and USGS National Center for Earth Resources Observation Science: (tc); NASA: JSC (bc). 10 Corbis: Roger Ressmeyer (cla); SPL: ESA (tl); Jisas/ Lockheed (cl); SOHO: (clb). 11 SPL: Scharmer et al/ Royal Swedish Academy of Sciences.

12 GPL: JPL. 13 ESA: DLR/FU Berlin (G. Neukum) (tr); NASA: JPL (cra), (crb); JPL/STScI (trb). 14 Chandra: NASA/CXC/MIT/F.K. Baganoff et al. (tl); NOAO: Eric Peng (JHU), Holland Ford (JHU/ STScI), Ken Freeman (ANU), Rick White (STScI) (cla); T.A. Rector and Monica Ramirez (clb). 15 © 2005 Russell Cromon (www.rcastro.com). 16 2MASS: T.H. Jarrett, J. Carpenter, & R. Hurt (cla); Chandra: X-Ray: NASA/CXC/ESO/P. Rosati et al; Optical: ESO/VLT/P. Rosati et al. (clb); SPL: Carlos Frenk, Univ. of Durham (tl). 17 NASA: ESA, A. van der Wel (Max Planck Institute for Astronomy, Heidelberg, Germany), H. Ferguson and A. Koekemoer (STScI), and the CANDELS team. 18–19 Corbis: Roger Ressmeyer. 20–21 NASA: HST/HHT (STScI/AURA). 22 Credner: (br); NASA: HST/Dr Michael S.Vogeley – Princetown Univ. Obs. (bc). 23 NASA: HST/ESA, Richard Ellis (Caltech) and Jean-Paul Kneib (Observatoire Midi-Pyrenees, France) (tc). 24 NASA: HST/ESA and J. Hester (ASU) (b); NOAO: Nathan Smith, Univ. of Minnesota (tr); SPL: J-C Cuillandre/Canada–France–Hawaii Telescope (cla). 25 Corbis: (tcr); GPL: Andrea Dupree, Ronald Gilliland (STScI)/NASA/ESA (tcl); Damian Peach (tc); Nigel Sharp, NSF REU/AURA/NOAO (cr); STScI (tr); NASA: GSFC (bc); HST, HHT (STScI/AURA) (cl); JPL (cb/Europa), (cb/Ganymede), (cb/Io); JPL/DLR (German Aerospace Center) (cb/Callisto); SPL: Pekka Parviainen (br). 26 Chandra: NASA/CXC/U. Amsterdam/S. Migliari et al. (bl); NASA: HST/Jeffrey Kenney and Elizabeth Yale (Yale Univ.) (br); JPL – Caltech/ASU/Harvard– Smithsonian Center for Astrophysics/NOAO (cl); SPL: NOAO (c); STScI/NASA (tl). 26–27 NASA: HST/H. Ford (JHU), G. Illingworth (UCSC/LO), M. Clampin (STScI), G. Hartig (STScI), the ACS Science Team and ESA (tc). 27 Gemini Observatory/Association of

Universities for Research in Astronomy: Key: t = top; b = bottom/below; c = center; l = left; r = right; a = above.

A C K NO W LE DG ME N TS

Abbreviations: AAO = Anglo Australian Observatory; ASU = Arizona State University; BAL = Bridgeman Art Library (www. bridgeman.co.uk); Caltech = California Institute of Technology; Chandra = Chandra X-Ray Observatory; Credner = Till Credner www.allthesky.com; DSS = Digitized Sky Survey; ESA = European Space Agency; ESO = © European Southern Observatory, licensed through the Creative Commons Attribution 3.0 license - http://creativecommons.org/licenses/by/3.0/; GPL = Galaxy Picture Library; GSFC = Goddard Space Flight Center; HHT = The Hubble Heritage Team; HST = Hubble Space Telescope; JHU = John Hopkins University; JPL = Jet Propulsion Laboratory; JSC = Johnson Space Center; KSC = Kennedy Space Center; DMI = David Malin Images; MSFC = Marshall Space Flight Center; NASA = National Aeronautics and Space Administration; NOAO = National Optical Astronomy Observatory/Association of Universities for Research in Astronomy/National Science Foundation; NRAO = Image courtesy of National Radio Astronomy Observatory/AUI; NSSDC = National Space Science Data Center; SPL = Science Photo Library; SOHO = Courtesy of SOHO/EIT Consortium. SOHO is a project of international cooperation between ESA and NASA; STScI = Space Telescope Science Institute; TRACE = Image courtesy of the Lockheed Martin team of NASA’s TRACE Mission; USGS = U.S. Geological Survey.

GMOS–South Commissioning Team (tl); NASA: HST/N. Benitez (JHU),T. Broadhurst (The Hebrew Univ.), H. Ford (JHU), M. Clampin (STScI), G. Hartig (STScI), G. Illingworth (UCO/Lick Obs.), the ACS Science Team and ESA (ca); SPL: Los Alamos National Laboratory (br); Max-Planck-Institut für Astrophysik (crb). 28 NOAO: Todd Boroson (ca); SPL: Philippe Plailly (cl). 29 DK Images: Andy Crawford (cr); Clive Streeter/Courtesy of the Science Museum, London (crb); Colin Keates/Courtesy of the Natural History Museum, London (cb); Harry Taylor (ca); SPL: Lawrence Berkeley Laboratory (cra). 30 Corbis: Raymond Gehman (cla); SPL: Alfred Pasieka (tr); CERN (br). 31 SPL: CERN (cl); SOHO: (bc).

32–33 Courtesy of the National Science Foundation: B. Gudbjartsson. 34 DK Images: (clb). 34– 35 NASA: HST/HHT (STScI/AURA) (tc). 35 SPL: (bl). 36 2MASS: (cr); GPL: Rainer Beck/Philipp Hoernes/ MPIFR (clb); SPL: David Nunak (cla); Dr Fred Espenak (tr); courtesy of NASA/WMAP Science Team: (c, tc). 37 Chandra: NASA/SAO/CXC/G. Fabbiano et al. (cbr); NGST (car); GPL: EGRET Team (crb); Robin Scagell (tl); NASA: General Dynamics (cra); HST/ESA, R. Sankrit and W. Blair (JHU) (tr); Ultraviolet Imaging Telescope (cbl); NOAO: (clb); SPL: NASA (cal) 38 Corbis: (bl); NASA: JSC (br). 39 Alamy Images: Kolvenbach (br); NASA: JPL (t). 40 Corbis: (bl); Lester Lefkowitz (cl). 41 Corbis: (ca); Bettmann (bl). 42–43 SPL: W. Couch and R. Ellis/NASA (bc). 44 NOAO: Todd Boroson (bc). 45 NASA: HST/ESA, J. Blakeslee and H. Ford (JHU) (tc); SPL: Sanford Roth (cra).

46–47 NASA: HST/H. Ford (JHU), G. llingworth (UCSC/LO), M. Clampin (STScI), G. Hartig (STScI), the ACS Science Team, and ESA. 49 © CERN Geneva: (tc). 50 Corbis: Bettmann (tr). 51 Corbis: Bettmann (tc); NASA: HST/HHT (STScI/AURA) (tl). 52–53 © CERN: Maximilien Brice. 54 Image courtesy of Andrey Kravstov: Simulations were performed at the National Center for Supercomputing Applications (Urbana-Champaign, Illinois) by Andrey Kravtsov (The Univ. of Chicago) and Anatoly Klypin (New Mexico State Univ.).Visualizations by Andrey Kravtsov (b); SPL: courtesy of NASA/WMAP Science Team: (ca). 54–55 NASA: HST/K.L. Luhman (Harvard–Smithsonian Center for Astrophysics, Cambridge, Mass.); and G. Schneider, E.Young, G. Rieke, A.Cotera, H. Chen, M. Rieke, and R.Thompson (Steward Obs.,ASU,Tuscon,Ariz.) (c). 55 Chandra: NASA/ CXC/GSFC/U. Hwang et al. (br); NASA: HST/ ESA,A.M. Koekemoer (STScI), M. Dickinson (NOAO) and the GOODS Team (tr); SPL: NASA (c, crb). 56 Corbis: Roger Ressmeyer (br); NASA: Provided by the SeaWiFS Project, NASA/GSFC, and ORBIMAGE (tr); SPL: Dr Linda Stannard, UCT (c); John Reader (bl); MSFC/NASA (clb). 57 Courtesy of the NAIC– Arecibo Observatory, a facility of the NSF: (bl); NASA: JPL/AUS (cl); SETI League photo, used by permission: (br).

58 courtesy of Saul Perlmutter and The Supernova Cosmology Project: (bl). 59 SPL: Royal Obs., Edinburgh/AATB (bc). 60–61 Corbis: Roger Ressmeyer. 63 BAL: Bibliothèque des Arts Decoratifs, Paris, France/ Archives Charmet (cr); SPL: David Nunuk (tl). 64 British Library, London: shelfmark: Or.5259, folio: f.29 (cr); The Picture Desk: The Art Archive/ British Library, London (cl); SPL: Frank Zullo (tr). 64–65 Corbis: Paul A Souders (b). 66 Alamy Images: Robert Harding Picture Library (cl); SPL: John Sanford (b). 67 Corbis: Jeff Vanuga (tr); Royalty–Free (cb); DMI: Akiri Fujii (cr); The Picture Desk: The Art Archive/Biblioteca d’Ajuda, Lisbon/Dagli Orti (cla). 68 SPL: Pekka Parviainen (tr); Sheila Terry (clb); Tunc Tezel: (br). 69 Corbis: Carl and Ann Purcell (bc); GPL: Jon Harper (cr); The Picture Desk: The Art Archive/British Library, London, UK (br); SPL: Eckhard Slawik (tl, tr); John Sanford (bl). 70 SPL: ESA (cl). 71 AAO: Photograph by David Malin (l); SPL: John Chumack (cr); Rev. Ronald Royer (c).

72 courtesy of the Archives, California Institute of Technology: (bl); Corbis: Stapleton Collection (tl). 73 BAL: Private Collection/Archives Charmet (bl); NOAO: (bcl, br); Jeff Hageman/Adam Block (cr); Joe Jordan/Adam Block (cbr); N.A. Sharp (cbl); Peter Kukol/ Adam Block (tr);Yon Ough/Adam Block (bcr). 74 Corbis: Digital image © 1996 Corbis; original image courtesy of NASA (cla); SPL: Chris Madeley (r); Stephan J Krasemann bl. 75 Credner: (bc, tcl); NAOJ: H. Fukushima, D. Kinoshita, and J. Watanabe (tr); Nature Publishing Group (www.nature.com): Victor Pasko (bcl); Polar Image/Pekka Parviainen: (cr); SPL: Magrath/Folsom br. 76 DK Images: (bl); GPL: Dave Tyler (c, ca); Robin Scagell (r); NASA: C. Mayhew and R. Simmon (NASA/ GSFC), NOAA/NGDC, DMSP Digital Archive (cl); SPL: Frank Zullo (clb). 77 DK Images: Andy Crawford (tr). 78-79 Novapix: S.Vetter. 80 DK Images: (cl); courtesy of John W. Griese: (bl); SPL: Frank Zullo (r). 81 Credner: (cbl); DK Images: (tl, tr); GPL: Robin Scagell (cl, cr, bcl, bcr, br). 82 Corbis: Bettmann (cra); DK Images: (bl, bc, crb); courtesy of the Science Museum, London/Dave King (ca); Science and Society Picture Library: Science Museum, London (cl). 83 DK Images: (t, bl); Dreamstime.com: Fotum (crb/Magnification); GPL: Robin Scagell (cr/Aperture). 84 DK Images: (clb, bl, bcr, br); Dreamstime.com: Vinicius Tupinamba (cbl/finderscope view, bcl/red dot view); GPL: Celestron International (tr). 85 Corbis: Roger Ressmeyer (cla, cal); DK Images: (tc, trb, clb); GPL: Rudolf Reiser (cbl); Robin Scagell (car, cra); Getty Images: SSPL/Babek Tafreshi (b). 86–87 DK Images. 88 Corbis: Science Faction/Tony Hallas (cl); DK Images: (tr, bl, br); Dreamstime.com: Neutronman (cr); Will Gater: (bc). 89 DK Images: (tl, c, cr); GPL: Philip Perkins (bl); Dave Tyler (br); SPL: J-P Metsavainio (cra). 90 Corbis: Roger Ressmeyer (tr, cl, cr); ESO: (b). 91 Corbis Dusko Despotovic (cla); ESO: G Hüdepohl/ www.atacamaphoto.com (tr); Getty Images: Photolibrary/Robert Finken (br); W.M. Keck

Observatory: UCLA Galactic Center Group (crb); Photo courtesy of the Large Binocular Telescope Observatory: The LBT is an international collaboration among institutions in the United States, Italy and Germany (clb).

92–93 ALMA Observatory: Babak Tafreshi. 94 ESA: C. Carreau (bl); NASA: ESA, and HHT (STScI/AURA)/J. Blakeslee (JHU) and R. Thompson (University of Arizona) (br); HST (c); ESA (r). 95 ESA: C. Carreau (crb); LFI & HFI Consortia (cla); CNESArianespace/Optique Vidéo du CSG - L. Mira (tr); Khosroshani, Maughan, Ponman, Jones (bl). 96–97 NASA: JPL/STScI. 98–99 TRACE. 100 akg-images: (c); NASA: JPL (cb). 101 NASA: JPL (c). 102 SPL: (tr). 103 Corbis: Yann Arthus-Bertrand (ca); NASA: Erich Karkoschka (ASU Lunar and Planetary Lab) and NASA (tcl). 105 NASA: GSFC (br); SPL: Julian Baum (cr); SOHO: (l, crb). 106 SPL: John Chumack (cr); NOAO (tr); SOHO: (b, cl). 107 Alamy Images: Steve Bloom Images (bl); Science and Society Picture Library: Science Museum, London (cla); SPL: Chris Butler (cra); Jerry Rodriguess (tr); SOHO: (clb); TRACE: (c); A. Title (Stanford Lockheed Institute) (cr).

108–109 © Alan Friedman/avertedimagination. com 110 NASA: John Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington (r); University of Colorado/John Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington (ca). 111 NASA: University of Colorado/John Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington (cb); SPL: A.E. Potter and T.H. Morgan (crb). 112 GPL: NASA/JPL/Northwestern Univ. (tr); NASA: John Hopkins University Applied Physics Laboratory/ Carnegie Institution of Washington (bl, br); NSSDC/ GSFC/NASA: Mariner 10 (c). 113 GPL: NASA/JPL/ Northwestern Univ. (br, tr); NASA: JPL/Northwestern Univ. (cl); John Hopkins University Applied Physics Laboratory/ASU/Carnegie Institution of Washington. Image reproduced courtesy of Science/AAAS (c); John Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington (bl, bcl); SPL: NASA (bcr). 115 NASA: JPL (bc); SPL: NASA: (l). 116 ESA: (bl); NASA: Ames Research Center (cl); JPL (tr, c, cr); NSSDC/GSFC/NASA: Magellan (cra); Venera 13 (clb);Venera 4 (tl). 117 NASA: JPL (tl, cla); NSSDC/GSFC/NASA: Magellan (tcr); SPL: NASA (cr, trb). 118 NASA: JPL (bl, cr, cl, tr); NSSDC/GSFC/NASA: Magellan (c, ca); SPL: David P. Anderson, SMU/NASA (br). 119 NASA: JPL (bc, br, cla, cal, cb); NSSDC/ GSFC/NASA: Magellan (car, tr). 120 NASA: JPL (tc, tr); SPL: David P. Anderson, SMU/ NASA (b). 121 NASA: JPL (tl, c, crb, bl, bc, br); SPL: David P. Anderson, SMU/NASA (cra). 122 NASA: JPL (tl, cl, cr, br); NSSDC/GSFC/NASA: Magellan (c, bc). 123 NASA: JPL (tr, cl, ca, bl, br); NSSDC/GSFC/NASA: Magellan (cb). 125 NASA: GSFC. Image by Reto Stöckli, enhancements by Robert Simmon (l); SPL: Emilio Segre Visual Archive/ American Institute of Physics (crb). 127 Corbis: Jamie Harron/Papillio (tc); DK Images: (cb/fungi);Andrew Butler (cb/plants); Geoff Brightling (cb/animals); M.I.Walker (cb/protists); FLPA – Images of Nature: Frans Lanting (tl); SPL: Scimat (cb/ monerans).

128–129 NASA Visible Earth/EOS Project Science Office: Jeff Schmaltz. 130 Alamy Images: FLPA (crb); Corbis: image by Digital image © 1996 Corbis; original image courtesy of NASA (cra); Lloyd Cluff (tl); Robert Gill/Papilio (cl); Sygma/PierreVauthey (bcr); National Geographic Image Collection: Image from Volcanoes of the Deep, a giant screen motion picture, produced for IMAX Theaters by the Stephen Low Company in association with Rutgers Univ. Major funding for the project is provided by the National Science Foundation (bl). 131 Corbis: (br); Jon Sparks (bl); Kevin Schafer (t); Michael S Yamashita (crb); NASA: ASF/JPL (c); 132 Corbis: Craig Lovell (tc, cb); Macduff Everton (bl);

Landsat 7 satellite image courtesy of NASA Landsat Project Science Office and USGS National Center for Earth Resources Observation Science: (cla). 133 NASA: JSC – Earth Sciences and Image Analysis.

134 Corbis: Elio Ciol (cal); image by Digital image © 1996 Corbis; original image courtesy of NASA (bl); Layne Kennedy (br); Tom Bean (tl); NASA: GSFC/JPL, MISR Team (crb); JSC – Earth Sciences and Image Analysis (cra). 135 Corbis: (tl); Galen Rowell (cr, b); Marc Garanger (tr); NASA: JPL (cl).

ACKNOWLEDGMENTS 136–137 Michael Light (www.projectfullmoon. com): (c). 138 akg-images: (cla); Corbis: Roger Ressmeyer (cra); NASA: JSC (c); MSFC (b); SPL: ESA, Eurimage (trb). 139 Corbis: Roger Ressmeyer (cr); ESA: Space-X, Space Exploration Institute (bc); Galaxy Contact: NASA (ca) GPL: Thierry Legault (tr); NSSDC/GSFC/NASA: Lunar 3 (crb); Scala Art Resource: Biblioteca Nazionale, Florence, Italy (clb); USGS: (cbr). 140 NASA: LRO/LOLA Science Team (tr). 142–143 NASA. 144 NASA: JSC (bl); JPL (tl); NSSDC/GSFC/ NASA: Apollo 11 (br); Galileo (crb); Lunar Orbiter 5 (cl); SPL: John Sanford (cra). 145 GPL: Damian Peach (bl); NASA: (bc); JPL (cla); NSSDC/GSFC/NASA: Apollo 17 (tc); Lunar Orbiter 5 (br); Ranger 9 (cra); USGS/Clementine (crb). 146 NASA: JSC (tc, cra). 146–147 Michael Light (www.projectfullmoon.com): (b). 147 NASA: JSC (tl); NSSDC/GSFC/NASA: Apollo 17 (tr). 148 ESA: Space-X, Space Exploration Institute (cl); GPL: NASA (cr, bc); NSSDC/GSFC/NASA: Apollo 15 (tc); Lunar Orbiter 3 (c); U.S Department of Energy: (br). 149 NASA: GSFC (cbr); GSFC/ASU/ Lunar Reconnaissance Orbiter (bl); JPL/USGS (tr); Lunar Prospector (bc); NSSDC/GSFC/NASA: Lunar Orbiter 4 (tc). 151 NASA: JPL (br); JPL-Caltech/University of Arizona (cr); USGS: (l). 152 ESA: DLR/FU Berlin (G. Neukum) (cr); NASA: Cornell University, JPL and M. Di Lorenzo et al. (ca); JPL (tr, cla, cl, bl); JPL/Cornell Univ./Mars Digital (clb); NSSDC/GSFC/NASA: Viking Orbiter 1 (tlb). 153 NASA: JPL-Caltech/MSSS (tr); JPL-Caltech/University of Arizona (tl, cla, cra). 154–155 NASA: JPL-Caltech/ASU. 156 ESA: DLR/FU Berlin (G. Neukum) (tr); NASA: JPL/ASU (cl); JPL/MSSS (cal, cra, crb, bl, br). 157 ESA: DLR/FU Berlin (G. Neukum) (bl); NASA: JPL (trb); JPL-Caltech/University of Arizona (br); JPL/MSSS (cal, cla). 158 NASA: JPL/MSSS (tc, ca). 158–159 NASA: JPL/USGS b. 159 ESA: DLR/FU Berlin (G. Neukum) (tc, cla, cra); NASA: JPL/MSSS (tcb). 160 ESA: DLR/FU Berlin (G. Neukum) (tc, tr, ca, cr); NASA: JPL/ASU (tlb); JPL/MSSS (c, bl); JPL-Caltech/ University of Arizona (br). 161 ESA: DLR/FU Berlin (G. Neukum) (b); NASA: JPL/MSSS (cl); JPL/USGS (tr); JPL-Caltech/University of Arizona (cra). 162 ESA: DLR/FU Berlin (G. Neukum) (bl); NASA: JPL (cl); JPL/MSSS (tc, br); JPL-Caltech/University of Arizona (cr). 163 ESA: DLR/FU Berlin (G. Neukum) (bl); OMEGA (bc); NASA: JPL/Cornell (tc, ca); JPL-Caltech/University of Arizona (crb). 164 ESA: DLR/FU Berlin (G. Neukum) (tr, br); NASA: JPL/ASU (cbl); JPL/Cornell (cla); JPL/MSSS (cra); JPL-Caltech/University of Arizona (clb); Mars Orbiter Laser Altimeter (MOLA) Science Team (crb). 165 ESA: DLR/FU Berlin (G. Neukum) (cra, bc); NASA: JPL/MSSS (tr, cb, br); JPL/USGS (tl); Mars Global Surveyor/USGS (bl). 166 NASA: JPL/Cornell (tr, cla). 166–167 NASA: JPL/Cornell (b). 167 NASA: JPL (tl); JPL/Cornell (tc, tr). 168–169 NASA: JPL/University of Arizona. 170 NASA: HST/R. Evans and K. Stapelfeldt (JPL) (cl). 171 DK Images: (tc). 172 ESA: © 2008 MPS for OSIRIS Team MPS/UPD/ LAM/IAA/RSSD/INTA/UPM/DASP/IDA (cbr, bc, bl); NASA: JPL-Caltech (c/left; c/right); JPL/JHU/APL (tr, br); JPL/USGS (cl); NSSDC/GSFC/NASA: Goldstone DSC antenna-radar (cr). 173 GPL: NASA/ JPL (b); NASA: JPL (tr). 174 Corbis: R Kempton (tr); NASA: JPL-Caltech/ UCLA/MPS/DLR/IDA (ca, b). 175 Japan Aerospace Exploration Agency (JAXA): (crb, bl, br); SPL: Dennis Milon (cla); Mark Garlick (ca); courtesy of

Osservatorio Astronomico di Palermo Giuseppe S.Vaiana: (cra). 176 NASA: JPL/JHU/APL (cla, clb, bl); SPL: NASA (tc). 177 GPL: NASA/JPL/JHU/APL. 179 GPL: NASA/JPL/ASU (l); NASA: HHT (STScI/

182 Laurie Hatch Photography/Lick Observatory: (cbl); NASA: JPL/Cornell Univ. (cal, car, cl, bl); JPL/Lowell Obs. (cra); JPL/ASU (tl); courtesy of Scott S. Sheppard, University of Hawaii: (bcr). 183 DK Images: Andy Crawford (cra); GPL: NASA/ JPL/DLR (German Aerospace Center)/ASU (b); NASA: JPL/DLR (German Aerospace Center) (tcl, tcr, cla). 184 GPL: NASA/JPL (tc); NASA: JPL/PIRL/ASU (cl); JPL/ASU (bl); JPL/ASU/LPL (br). 185 GPL: NASA/JPL/USGS. 186 GPL: NASA/JPL/DLR (German Aerospace Center) (t); NASA: JPL (bl); JPL/Brown Univ. (crb, br). 187 BAL: Private Collection (crb); GPL: NASA/JPL

Nicholson, Joseph Burns, and JJ Kavelaars, using the 200 inch Hale Telescope: (br); NASA: JPL (tl, tr, clb, bl, bc).

205 GPL: NASA/JPL (l); NASA: JPL (crb); JPL/ HST (cra). 206 Corbis: Roger Ressmeyer (bc); NASA: JPL (tl, bl, br); NSSDC/GSFC/NASA: Voyager 2 (cl, c/left); SPL: NASA (c/right). 207 Liverpool Astronomical Society: With thanks to Mike Oates (br); NASA: JPL/ USGS (t, clb); courtesy of A.Tayfun Oner: (bc). 208 Corbis: Bettmann (br); NASA: ESA and P. Kalas (University of California, Berkeley) (bl); HST/M. Brown (Caltech) (clb); NSSDC/GSFC/NASA: Denis Bergeron, Canada (cl). 209 ESO: (br); Lowell Observatory Archives: (cra); NASA: ESA and M. Showalter (SETI Institute) (cr); ESA and M. Buie (Southwest Research Institute) (bl). 210 W.M. Keck Observatory: Mike Brown (California Institute of Technology) (clb); NASA: ESA and M. Brown (California Institute of Technology) (bc); HST/Mike Brown (California Institute of Technology) (cla). 211 Corbis: Jonathan Blair (cra); GPL: Michael Stecker (c); NASA: JPL-Caltech (cb, br). 212 SPL: Pekka Parviainen (tr). 213 Corbis: Jonathan Blair (cra); DK Images: (b); NASA: JPL/Brown Univ. (cl); JPL/USGS (ca); SOHO: (clb). 214 akg-images: (c); DK Images: (cr); NOAO: Roger Lynds (bl); SPL: Pekka Parviainen (bc); Detlev van Ravenswaay (tr); Rev. Ronald Royer (crb). 215 ESO: Peter Stättmayer of the Munich Public Obs. (bl); DMI: Akira Fujii (cr); SPL: John Thomas (tr); James V.

Scotti, Spacewatch Project of the Lunar and Planetary Laboratory, ASU. © 1994 by the Arizona Board of Regents. Reproduced by permission: (bc). 216 Corbis: Gianni Dagli Orti (cr); ESA: MPAE, 1986, 1996 (cl); SPL: Frank Zullo (b); Richard J.Wainscoat, Peter Arnold Inc. (tr). 217 Rolando Ligustri/CAST Circolo AStrofili Talmassons, Italy: (tc, ca); courtesy of Lowell Observatory: (br); NASA: JPL (cr); JPL-Caltech (cb, bc/left); SPL: (cl); STScI/NASA (bc/right).

218 NASA: JPL/UMD (tc); JPL-Caltech/UMD (tr, br); JPL-Caltech/LMSS (cl). 219 ESO: S. Deiries (t). NASA: Dan Burbank (ISS) (crb); Solar Dynamics Observatory (SDO) (bl). 220 GPL: Arne Danielsen (cl); © The Natural History Museum, London: (crb, bc, br); SPL: (cr, bl); David McLean (ca). 221 Corbis: Jonathan Blair (bl); DK Images: Harry Taylor (cb, bc); Getty Images: NASA/ AFP (t); NASA: Carnegie Mellon Univ./Robotic Antarctic Explorer (LORAX) (br). 222 Corbis: Matthew McKee/Eye Ubiquitous (bl); DK Images: courtesy of the Natural History Museum, London/Colin Keates (c); GPL: UWO/Univ. of Calgary (cl); Muséum National d’Histoire Naturelle, Paris: Département Histoire de la Terre (bc); © The Natural History Museum, London: (br); SPL: D. van Ravenswaay (cbr); Michael Abbey (cr); Pascal Goetgheluck/Francois Robert (tr). 223 Alamy Images: H.R. Bramaz (cla); NASA: JSC (br); KSC (crb); © The Natural History Museum, London: (tr, bl). 224–225 John P. Gleason, Celestial Images 226 SPL: Chris Butler (cra); Tony and Daphne Hallas (tr); Planetary Visions: (b). 227 Corbis: Image by © National Gallery Collection; by kind permission of the Trustees of the National Gallery, London (cr); NASA: D. Dixon (UCR), D. Hartmann (Clemson), E. Kolaczyk (U. Chicago) (cl); JPL-Caltech (tl). 228 NASA: HST/Jeff Hester (ASU) (tr); NOAO:

Adam Block (b). 229 Reprinted by permission of

American Scientist, magazine of Sigma Xi, the Scientific Research Society: (car); NRAO: (cr, cr/ inset); SPL: (bl); B.J. Mochejska (CfA), J. Kaluzny (CAMK), 1m Swope Telescope: (bc). 230–231 NASA: X-Ray: CXC/UMass/D. Wang et al; Optical: ESA/STScI/D. Wang et al; IR: JPL-Caltech/ SSC/S. Stolovy. 233 Courtesy of Andy Steere: (bl); Corbis: Bettmann (br); GPL: Andrea Dupree, Ronald Gilliland (STScI)/NASA/ESA (cra); Robin Scagell (cr); SOHO: (tl). 234 NASA: HST/Wolfgang Brandner (JPL/IPAC), Eva K. Grebel (Univ. Washington),You-Hua Chu (Univ. Illinois Urbana-Champaign) (tr). 235 NASA: HST/C.A. Grady (NOAO, NASA, GSFC), B.Woodgate (NASA, GSFC), F. Bruhweiler and A. Boggess (Catholic Univ. of America), P. Plait and D. Lindler (ACC, Inc., GSFC), and M. Claupin (STScI) (br). 236 Courtesy of Andy Steere: (bl). 237 Chandra: NASA/STScI/R. Gilliand et al. (tl). 238 AAO: Photograph by David Malin (car); ESO: APEX/DSS2/SuperCosmos/Deharveng (LAM)/Zavagno (LAM) (tr); NASA: HST/J. Hester and P. Scowen (ASU) (cr); NOAO: Gemini Obs./Travis Rector, Univ. of Alaska, Anchorage (b). 239 courtesy of Armaugh

Observatory: (bc/left); NASA: HST/ESA and HHT (STScI/AURA) (cl); HST/J. Hester (ASU) (tr); HST/Kirk Borne (STScI) (tc); C. and F. Roddier (IfA, Hawaii), CFHT: (bra). 240 ESO: J. Alves (ESO), E.Tolstoy (Groningen), R. Fosbury (ST–ECF), and R. Hook (ST–ECF) (VLT) (cl); Leonardo Testi (Arcetri Astrophysical Obs., Florence, Italy (NTT + SOFI) (tl); NOAO: T.A. Rector (NOAO) and HHT (STScI/AURA/NASA) (bc). 241 ESO: J. Emerson/VISTA/Cambridge Astronomical Survey Unit (l); Mark McCaughrean (Astrophysical Institute, Potsdam, Germany (VLT,ANTU, and ISAAC) (tc); © Smithsonian Institution: (br). 242 NASA: HST/H. Ford (JHU), G. Illingworth (UCSC/LO), M. Clampin (STScI), G. Hartig (STScI), the ACS Science Team and ESA (tc); NOAO: Michael Gariepy/Adam Block (br); T.A. Rector (NRAO/AUI/ NSF and NOAO) and B.A. Wolpa (NOAO) (cl). 243

Geert Barentsen & Jorick Vink (Armagh Observatory) & the IPHAS Collaboration: (tr); Richard Crisp (www.narrowbandimaging. com): (tc); NASA: JPL – Caltech/S. Carey (Caltech) (bl); NOAO: N.A. Sharp, REU Program (cb); SPL: Mount Stromlo and Siding Spring Observatories (bc). 244 NASA: HST/ESA, STScI, J. Hester, and P. Scowen (ASU) (bl); NOAO: T.A. Rector (NRAO/AUI/NSF and NOAO) and B.A.Wolpa (NOAO) (tc). 245 ESO: (VLT,ANTU + ISAAC). 246 NASA: HST/HHT (STScI/AURA) (cla); JPL-Caltech (tr); NOAO: Todd Boroson (bl); SPL: National Optical Astronomy Observatories (br). 247 2MASS: E.Kopan (IPAC)/Univ. of Massachusetts (tc); NASA: ESA and M. Livio and the Hubble 20th Anniversary Team (STScI) (bl); JPL-Caltech/Spitzer Space Telescope (br); JPL-Caltech/Univ. of Wisconsin (tr). 248–249 NASA: ESA, N. Smith (University of California, Berkeley), and HHT (STScI/AURA). 250 GPL: Gordon Garradd (cl); SOHO: (b); TRACE: (tr). 251 Corbis: Bettmann (cl); SOHO: (tr). 252 GPL: Duncan Radbourne (bl); DMI: Akira Fujii (tr); NASA: HST/HHT (AURA/STScI) (cl); SPL: Dr. Fred Espenak (cr); Eckhard Slawik (br); NOAO (c). 253 GPL: Deep Sky Survey (clb); DMI: Akira Fujii (tr, cla); NASA: ESA, P. Kalas, J. Graham, E. Chiang, E. Kite (University of California, Berkeley), M. Clampin (NASA GSFC), M. Fitzgerald (Lawrence Livermore National Laboratory), and K. Stapelfeldt and J. Krist (NASA JPL) (tc, tc/inset); courtesy of Joe Orman: (cb); SPL: Eckhard Slawik (bc); 254 Matt BenDaniel (http://starmatt.com): (bl); Credner: (cla). 255 NASA: HST/Bruce Balick (Univ. of Washington), Jason Alexander (Univ. of Washington), Arsen Hajian (U.S. Naval Obs.),Yervant Terzian (Cornell Univ.), Mario Perinotto (Univ. of Florence, Italy), Patrizio Patriarchi (Arcetri Obs. Italy) (bc); HST/Bruce Balick (Univ. of Washington),Vincent Icke (Leiden Univ.,The Netherlands), Garrett Mellema (Stockholm Univ.) (crb); HST/HHT (STScI/AURA) (l); HST/HHT (STScI/ AURA) (c); HHT (STScI/AURA); D. Garnett (Univerity of Arizona) (cra). 256 ESO: P. Kervella (cr). Haubois et al., A&A, 508,

2, 923,2009, reproduced with permission © ESO/Observatoire de Paris: (cra); NASA: HST/ Jon Morse (Univ. of Colorado) (tl); H. Olofsson (Stockholm Observatory) et al: (br); SPL: Eckhard Slawik(cla); Royal Obs., Edinburgh/AAO (bc). 257 NASA: HST/Bruce Balick (Univ. of Washington),Vincent Icke (Leiden Univ., The Netherlands), Garrett Mellema (Stockholm Univ.) (br); HST/NOAO, ESA, the Hubble Helix Nebula Team, M. Meixner (STScI), and T.A. Rector (NRAO) (tr, cr); NOAO: Adam Block (bc). 258 R. Corradi (Isaac Newton Group), D. Goncalves (Inst. Astrofisica de Canarias): (cb); NASA: HST/ESA/Hans van Winckel (Catholic Univ. of

Leuven, Belgium) and Martin Cohen (Univ. of California Berkely) (t); HST/ESA, HEIC, and HHT (STScI/AURA) (bc); HST/HHT (STScI/AURA);W. Sparks (STScI) and R. Sahai (JPL) (br). 259 W. M. Keck Observatory: U.C. Berkeley Space Sciences Laboratory (clb); NASA: HST/ Andrew Fruchter and ERO Team (Sylvia Baggett (STScI), Richard Hook (ST–ECF), and Zoltan Levay (STScI) (br); STScI (cla); SPL: NOAO (cra). 260–261 NASA: ESA and the Hubble SM4 ERO Team. 262 ESO: (br); NASA: ESA and Valentin Bujarrabal (Observatorio Astronomico Nacional, Spain) (cla); HST/ HHT (STScI/AURA) (tr); SPL: Dr Kris Davidson (c). 263 NASA: HST/Raghvendra Sahai and John Trauger (JPL), the WFPC2 Science Team. 264 NASA: HST/Matt Bobrowsky (Orbital Sciences Corporation) (br); HST/Yves Grosdidier (Univ. of Montreal and Observatoire de Strasbourg),Anthony Moffat (Univ. of Montreal), Gilles Joncas (Univ. Laval), Agnes Acker (Observatoire de Strasbourg) (cl); NOAO: Peter and Suzie Erickson/Adam Block (tr); © Observatoire de Paris: bl); SPL: Celestial Image Co. (tc). 265 ESO: W. Brandner (UIUC) et al, ESO, 1.54-m Telescope, Chile (bl); NASA: HST (br); HST/HHT (AURA/STScI) (t). 266 Chandra: NASA/U. Mass/D.Wang et al. (c); NASA: ESA and L. Bedin (STScI) (tr); ESA and P. Challis (Harvard-Smithsonian Center for Astrophysics) (bl). 268 Chandra: NASA/CXC/SAO (tr); NASA/SAO/ CXC (cl); ESO: M. van Kerkwijk (Institute of Astronomy, Utrecht), S. Kulkarni (Caltech),VLT Kueyen (cr); NASA: Compton Gamma Ray Obs. (cbl); HST/Fred Walter (State Univ. of New York at Stony Brook) (cra); HST/HHT (AURA/STScI) (crb). 269 AAO: Royal Obs., Edinburgh. Photograph from UK Schmidt plates by David Malin (crb); Chandra: G. Pavlov, M.Teter, O. Kargaltsev, D. Sanwal (PSU), CXC, NASA (b); NASA: HST/Jeff Hester (ASU) (cra); William P. Blair and Ravi Sankrit (JHU) (t). 270 NASA: X-Ray: CXC/J. Hester (ASU); Optical: ESA/J. Hester & A. Loll (ASU); Infrared: JPL-Caltech/R. Gehrz (Univ. Minn.). 271 NASA: CXC/MSFC/M. Weisskopf et al. (bc); SPL: Dr S. Gull and Dr J. Fielden (cr); GSFC/NASA (tr). 272 Corbis: (bl); GPL: Michael Stecker (cra); NASA: HST/ESA, CXO, and P. Ruiz-Lapuente (Univ. of Barcelona) (bc); HST/H. Richer (Univ. of British Columbia) (cla); SPL: Dr S. Gull and Dr J. Fielden (crb); Royal Greenwich Obs. (ca). 273 Chandra: NASA/ CXC/GSFC/U. Hwang et al. (bl); NASA: ESA, R. Sankrit, and W. Blair (JHU) (tr); HST/Dave Bennett (Univ. of Notre Dame, Indiana) (cbr); HST/ESA and HHT (STScI/AURA) (tc); HST/NOAO, Cerro Tololo Inter-American Obs. (br); NOAO: Doug Matthews and Charles Betts/Adam Block (c). 274 Science Photo Library: (cra). 275 ESO: Mark McCaughrean (Astrophysical Institute Potsdam, Germany) (VLT ANTU + ISAAC). 276 GPL: Damian Peach (cra, crb); Robin Scagell (bc);

courtesy of Padric McGee, University of Adelaide: (cl); NASA: HST/K.L. Luhman (Harvard– Smithsonian Center for Astrophysics, Cambridge, Mass.), G. Schneider, E.Young, G. Rieke, A.Cotera, H. Chen, M. Rieke, and R.Thompson (Steward Obs., ASU) (tl); SPL: Eckhard Slawik (cr, bl). 277 GPL: Damian Peach (c); NOAO: (cra); Johannes Schedler, Panther Observatory, Austria: (cl, cla); SPL: Dr. Fred Espenak (b); John Sanford (tr). 278 AAO: Photograph by David Malin. 279 GPL: Damian Peach (crb); The Picture Desk: The Art Archive/National Library, Cairo/Dagli Orti (bc); SPL: Tony and Daphne Hallas (cr). 280 SPL: Celestial Image Co. (tc, b). 281 AAO: Photograph by David Malin (bc/left); GPL: Duncan Radbourne (bl); SPL: George Fowler (bc/right); John Sanford (cl, br); Matthew Spinelli: (c); courtesy of

Thomas Williamson, New Mexico Museum of Natural History and Science: (cr). 282 Credner: (tr); NASA: HST/F. Paresce, R. Jedrzejewski (STScI) and ESA (c). 282–283 NASA: HST/ESA and HHT (STScI/AURA) (b). 283 NASA: ESA and H. Bond (STScI) (br/2006); HST (tr); SPL: Mark Garlick (cl).

284 GPL: DSS (N) (tl); infoastro.com/Victor R. Ruiz: (c); Johannes Schedler, Panther Observatory, Austria: (crb); SPL: John Sanford (cl, cl/ insert); courtesy of Jerry Xiaojin Zhu, Carnegie Melon University: (br). 285 Credner: (tr); courtesy of Mark Crossley: (cl/left); GPL: Damian Peach (cl/ right); NASA: HST/Margarita Karovska (Harvard– Smithsonian Center for Astrophysics) (cra); JPL-Caltech (cr); NOAO: Tom Bash and John Fox/Adam Block (b); SPL: Eckhard Slawik (crb); 286 GPL: DSS (N) (c); DSS (S) (cl); Robin Scagell (crb);

Sean Lockwood and David Yeaton-Massey, Leuschner Observatory, Lafayette, CA: (cr); SPL: (cra). 287 Matt BenDaniel (http://starmatt.com): (tr); GPL: Martin Mobberley (crb); NASA: HST/F. Paresce, R. Jedrjejewski (STScI), ESA (br); SPL: NOAO (bc). 288 © 2005 Loke Tan (www.starryscapes.com): (b); NOAO: Heidi Schweiker (tr). 289 Credner: (bl); ESO: (ANTU UT1 + TC) (tl); NASA: HST/HHT (AURA/STScI) (c).

A C KN OW L ED G M EN TS

AURA); NASA/ESA, John Clarke (Univ. of Michigan) (cr). 180 NASA: HST/ESA, and E.Karkoschka (ASU) (cb); JPL/STScI (tl). 181 NASA: HST/Dr. Hal Weaver and T. Ed Smith (STScI) (clb); JPL (tr); JPL/Cornell (crb); M. Wong and I. de Pater (University of California, Berkeley) (cla).

(b); NASA: JPL/ASU (tr); JPL/DLR (German Aerospace Center) (tc, cla). 189 NASA: HST/ESA, J. Clarke (Boston Univ.), and Z. Levay (STScI) (bl); JPL/STScI (tl). 190 NASA: JPL (tl); JPL-Caltech/STScI (tr); JPL/STScI (c, cb). 191 NASA: JPL-Caltech/University of Virginia (cra); JPL-Caltech/R. Hurt (SSC) (crb); JPL/STScI (clb, cbl); JPL/Univ. of Colorado (tr). 192 NASA: JPL (tr); JPL/STScI (cl, cra, crb, bl, br). 193 NASA: JPL/STScI (cla, clb, r). 194 NASA: JPL (br); JPL/STScI (tc, tr, cl, bl, bc); JPL/ STScI/Universities Space Research Association/Lunar & Planetary Institute (c). 195 NASA: JPL (tc, tr, cbr); JPL/ STScI (cl, bl); JPL/STScI/Universities Space Research Association/Lunar & Planetary Institute (br). 196 NASA: ESA/JPL/University of Arizona (bl); JPL/ Cassini is a cooperative project of NASA, the ESA, and the Italian Space Agency.The JPL, a division of Caltech, manages the Cassini mission for NASA’s Office of Space Science,Washington, D.C. (tr); JPL/STScI (cla, clb); JPL/ University of Arizona (br); JPL-Caltech/ASI (cra). 197 NASA: JPL/STScI (tl, tr, cbl, cr, br); JPL/ASU (bl). 198–199 NASA: JPL/STScI. 201 Corbis: Roger Ressmeyer (crb); GPL: JPL/STScI (l); W. M. Keck Observatory: Courtesy Lawrence Sromovsky, UW-Madison Space Science and Engineering Center (tr); NASA: JPL (cb). 202 NASA: HST/Erich Karkoschka (ASU) (tl); JPL (cl, c, bl, br); JPL/USGS (cb); NSSDC/GSFC/NASA: (cra). 203 Corbis: Sygma (c); Brett Gladman, Paul

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ACKNOWLEDGMENTS 290 NOAO: (bl, bc); N.A. Sharp, REU Program (crb); SPL: Celestial Image Co. (cra); Eckhard Slawik (cl); Jerry Lodriguss (cr); P. Seitzer (Univ. Michigan): (tl). 291 ESO: Das Universumisteine Scheibe (cr); NASA: HST/ HHT (STScI/AURA) (tc); SPL: Eckhard Slawik (cl); Tony and Daphne Hallas (b). 292–293 NASA: ESA and HHT (STScI/AURA). 294 AAO: Photograph by David Malin (br); 2009

Thomas V. Davis, www.tvdavisastropics.com: (cra); ESO: Y. Beletsky (cal); NASA: HST/HHT (STScI/AURA) (bc); NOAO: (cl); SPL: Dr. Fred Espenak (tr); © 2005 Loke Tan (www.starryscapes. com): (cb). 295 ESO: (c); NASA: HST/HHT (STScI/ AURA) (crb); NOAO: (tr, bc, br); Bruce Hugo and Leslie Gaul/Adam Block (bl); Michael Gariepy/Adam Block (cl). 296 ESO: A.-M. Lagrange et al. (bl); (SOFI + NTT) (tr); NASA: HST/ESA, C. Beichman (JPL), D.Ardila (JHU), and J. Krist (STScI/JPL) (cbr, br). 297 Canadian Space Agency: MOST (cr); ESA: CNES/D. Ducros (br); ESO: (NACO + VLT) (bl); NASA: Ames Research Center (bc); JPL-Caltech/R. Hurt (SSC) (cbr). 298 ESA: Alfred Vidal-Madjar (Insitute d’Astrophysique de Paris, CNRS, France) (bl); NASA: (tc); CXC/ Neuhauser et al. (crb); JPL-Caltech/H. Knutson (Harvard-Smithsonian CfA) (br); ESA and A. Feild (STScI) (ca). 299 NASA: Ames/JPL-Caltech (cr); JPL-Caltech (cl); Kepler Science Team: Jason Rowe (bl); Science Photo Library: Eurelios/Carlos Munoz-Yague (cla). 300–301 NASA: HST/ESA and HHT (AURA/STScI). 302 ESO: IDA/Danish 1.5 m/R. Gendler, S. Guisard (www.eso.org/~sguisard) and C. Thöne (br); NASA: HST/HHT (STScI/AURA) (tr, cr/Sb, bc); NOAO: (cra, cr/E0, cr/E6, cl; Adam Block (cr/E2, cr/Sa, cr/SBa, cr/ SBb); Jeff Newton/Adam Block (cr/S0); Jon and Bryan Rolfe/Adam Block (cr/Sc); Nicole Bies and Esidro Hernandez/Adam Block (cr/SBc); P. Massey (Lowell), N. King (STScI), S. Holmes (Charleston), G. Jacoby (WIYN) (clb); SPL: Royal Obs., Edinburgh (cla). 303 NASA: HST/HHT (STScI/AURA) (t); 304 AAO: Photograph by David Malin (cl, cr); NASA: HST/HHT (STScI/AURA) (bc, br); NOAO: (tc, c). 304–305 NASA: ESA, A. Aloisi (STScI/ESA), and HHT (STScI/AURA)-ESA/Hubble Collaboration (tc). 305 Chandra: NASA/SAO/G. Fabbiano et al. (br);

courtesy of D. A. Harper, University of Chicago: (bl); NASA: HST/ESA and D. Maoz (Tel-Aviv Univ. and Columbia Univ.) (tr); HST/R. de Grijs (Institute of Astronomy, Cambridge, UK) (cr); HST/ HHT (STScI/AURA) (cl). 306 ESA: AOES Medialab (br); SPIRE/HerschelATLAS/S.J. Maddox) (cl). 306–307 NASA: ESA, and HHT (STScI/AURA) (tc). 307 Robert A. Crain, Ian G. McCarthy, Carlos S. Frenk, Tom Theuns & Joop Schaye: (c/Row 3). Image courtesy of Rob Crain (Leiden Observatory, the Netherlands), Carlos Frenk (Institute for Computational Cosmology, Durham University) and Volker Springel (Heidelberg Institute of Technology and Science, Germany), partly based on simulations carried out by the Virgo Consortium for cosmological simulations: (c/Rows 1 and 2); NASA: AURA/STScI and WikiSky/SDSS (bl).

A C K NO W LE DG ME N TS

308 R. Jay GaBany, Cosmotography.com: Blackbird Observatory, D. Martínez-Delgado (IAC, MPIA), J. Peñarrubia (U.Victoria), I. Trujillo (IAC), S. Majewski (U.Virginia), M. Pohlen (Cardiff) (clb); NASA: J. English (University of Manitoba), S. Hunsberger, S. Zonak, J. Charlton, S. Gallagher (PSU) and L. Frattare (STScI) (cla); ESA, HHT (STScI/AURA) - ESA/Hubble Collaboration, and B. Whitmore (STScI) (br). 308–309 NASA: ESA, HHT (STScI/AURA) - ESA/Hubble Collaboration and K. Noll (STScI) (tc). 309 NASA: ESA and HHT (STScI/AURA)-ESA/Hubble Collaboration/B. Whitmore (STScI) and James Long (ESA/HST) (bl, bc); H. Ford (JHU), G. Illingworth (UCSC/LO), M. Clampin (STScI), G. Hartig (STScI), the ACS Science Team and ESA (cr). 310 NASA: ESA and B. Schaefer and A. Pagnotta (Louisiana State University, Baton Rouge)/CXC, SAO, HHT (STScI/AURA) and J. Hughes (Rutgers University) (cr); HHT (STScI/AURA) (br); NOAO: (tl); SPL: Max-Planck-Institut für Radioastronomie (bl); courtesy of www.seds.org: (cra). 311 Corbis: Visuals Unlimited (bl); Mary Evans Picture Library: (cra); NASA: HST/HHT (STScI/AURA) (br); NOAO: P. Massey (Lowell), N. King (STScI), S. Holmes (Charleston), and G. Jacoby (WIYN) (cr); SPL: Royal Obs., Edinburgh (tc). 312 Chandra: NASA/CXC/SAO (bc); NASA: UMass/Z. Li & Q.D. Wang (bl). 313 NASA: ESA and HHT (STScI/AURA) (bc); SPL: Tony and Daphne Hallas (t). 314 Chandra: NASA/CXC/SAO/PSU/CMU (cb); NASA: CXC/Wisconsin/D. Pooley & CfA/A. Zezas (tc); ESA and HHT (STScI/AURA) (tr); HST/HHT (STScI/AURA) (br); NOAO: Mark Westmoquette (Univ. College London), Jay Gallagher (Univ. of Wisconsin– Madison), Linda Smith (Univ. College London), WIYN, ESA, NASA (clb); N.A. Sharp (bl); SPL: GSFC (cla). 315 NASA: ESA, S. Beckwith (STScI), and HHT (STScI/

AURA) (b); JPL-Caltech/R. Kennicutt (University of Arizona)/DSS (tc/left); SPL: (cr); George Bernard (cra); Los Alamos National Laboratory (tc/right). 316 Corbis: Bettmann (br); NASA: HST/HHT (STScI/AURA) (c); X-Ray: UMass/Q.D. Wang et al.; Optical: STScI/AURA/HHT; Infrared: JPL-Caltech/ University of Arizona/R. Kennicutt/SINGS Team (cb); NOAO: George Jacoby, Bruce Bohamanm, and Mark Hanna (tr); SPL: Kapteyn Laboratorium (tc). 317 ESO: ALMA (ESO/NAOJ/NRAO;Visible Light Image: NASA/ESA HST (bc); NASA: ESA and HHT (STScI/ AURA)-ESA/Hubble Collaboration/B. Whitmore (STScI) and James Long (ESA/HST) (br); NOAO: (cla, cra); SPL: Celestial Image Co. (bl). 318 NASA: HST/H. Ford (JHU), G. Illingworth (UCSC/LO), M. Clampin (STScI), G. Hartig (STScI), the ACS Science Team and ESA (br); HST/HHT (STScI/ AURA) (ca, bl); SPL: Max-Planck-Institut für Astrophysik (crb); NOAO (bc). 319 DMI: Photograph by David Malin (br); NASA: HST/Kirk Borne (STScI) (cra); HST/HHT (STScI/AURA) (bc); SPL: STScI/ NASA (cla). 320 NOAO: Adrian Zsilavee and Michelle Qualls/ Adam Block (br); NRAO: (cb); SPL: Jodrell Bank (bc); STScI (crb). 320–321 Credner: (c/background). 321 ESO: S. Gillessen et al. (br); NASA: W. Purcell (NWU) et al., OSSE, Compton Obs. (crb); NOAO: Eric Peng, Herzberg Institute of Astrophysics/NRAO/AUI (tr); NRAO: (c). 322 Chandra: X-ray (NASA/CXC/M. Karovska et al); radio 21-cm image (NRAO/VLA/J.Van Gorkom/ Schminovich et al); radio continuum image (NRAO/ VLA/J.Condon et al); optical (DSS U.K. Schmidt Image/ STScI) (cr); ESO: Optical: WFI; Submillimetre: MPIfR/ ESO/APEX/A. Weiss et al.; X-Ray: NASA/CFX/CfA/R. Kraft et al. (cl); NASA: HST/Andrew S.Wilson (Univ. of Maryland); Patrick L. Shopbell (Caltech); Chris Simpson (Subaru Telescope);Thaisa Storchi- Bergmann and F. K. B. Barbosa (UFRGS, Brazil) and Martin J.Ward (Univ. of Leicester, U.K.) (cra); HST/E.J. Schreier (STScI) (br); NRAO: (tl). 323 courtesy of Vanderbilt Dyer Observatory: (cra); GPL: STScI (br); NASA: HST/L. Ferrarese (JHU) (bc); HST/HHT (STScI/AURA) (ca); HST/Walter Jeffe/Leiden Obs., Holland Ford/JHU/ STScI (bl); X-Ray: CXC/KIPAC/N. Werner, E. Million et al.; Radio: NRAO/AUI/NSF/F. Owen (cla). 324 NASA: ESA and Andy Fabian (University of Cambridge, UK) (tl); HST/J. Holtzman (cra); NRAO: (crb). 325 GPL: DSS (crb); STScI (cra); NASA: JPL-Caltech/Yale University (bl); HST/A, Martel (JHU), H. Ford (JHU), M. Clampin (STScI), G. Hartig (STScI), G. Illingworth (UCO/Lick Obs.), the ACS Science Team and ESA (cbl); courtesy of Cormac Reynolds, Joint

Institute for VLBI in Europe, The Netherlands: (cla); SPL: © Estate of Francis Bello (br). 326 NASA: HST/N. Benitez (JHU),T. Broadhurst (The Hebrew Univ.), H. Ford (JHU), M. Clampin (STScI), G. Hartig (STScI), G. Illingworth (UCO/Lick Obs.), the ACS Science Team, ESA (cr); SPL: Dr. Rudolph Schild (br); Royal Obs., Edinburgh (bc). 327 AAO: AURA/ Royal Obs., Edinburgh/UK Schmidt Telescope, Skyview (bl); Royal Obs. Edinburgh. Photograph from UK Schmidt plates by David Malin (clb); Chandra: NASA/ CXC/UCI/A. Lewis et al. (tlb); Pal. Obs. DSS (tl); ESO: (VLT UT1 + ISAAC) (cl); GPL: DSS/California Institute of Technology/Palomar Obs. (crb); NRAO: F.N. Owen, C.P. O’Dea, M. Inoue, and J. Eilek (br). 328 Matt BenDaniel (http://starmatt.com): (b); GPL: Robin Scagell (cla); NOAO: Local Group Galaxies Survey Team (cr); N.A. Sharp (tl); SPL: Celestial Image Co. (c). 329 Chandra: NASA/CXC/Columbia U./C. Scharf et al. (bl); ESO: FORS Team, 8.2 meter VLT Antu (cbr); NASA: HST/J. English (U. Manitoba), S. Hunsberger, S. Zonak, J. Charlton, S. Gallagher (PSU), and L. Frattare (STScI) (br); NOAO: Doug Matthews/Adam Block (cl); SPL: Celestial Image Co. (bc); Jerry Lodriguss (cla); Tony and Daphne Hallas (cr).

330–331 Rogelio Bernal Andreo (Deep Sky Colors). 332 AAO: Photograph by David Malin (cl); NASA: ESA and The Hubble SM4 ERO Team (tr, cb); HST/ HHT (STScI/AURA) (clb); HST/WFPC Team/STScI (br). 333 Dr. Victor Andersen (University of Alabama, KPNO), courtesy of W. Keel: (cla);

courtesy of the Archives, California Institute of Technology: (cra); Chandra: NASA/CXC/U. Mass/Q.D.Wang et al (bc/left); NASA/STScI and NOAO/Kitt Peak (bc/right); NASA: HST/N. Benitez (JHU),T. Broadhurst (The Hebrew Univ.), H. Ford (JHU), M. Clampin (STScI), G. Hartig (STScI), G. Illingworth (UCO/Lick Obs.), the ACS Science Team, ESA (ca); HST/W. Keel (Univ. Alabama), F. Owen (NRAO), M. Ledlow (Gemini Obs.), and D. Wang (Univ. Mass.) (br); NOAO: Jack Burgess/Adam Block (bl). 334 GPL: NASA – MSFC/Chandra/M. Bonamente et al. (br). 334–335 NASA: HST/Andrew Fruchter and the ERO Team – Sylvia Baggett (STScI), Richard Hook (ST–ECF), Zoltan Levay (STScI) (t). 335 Bell Labs, Lucent Technologies: Greg Kockanski, Ian Dell’Antonio, and Tony Tyson (br).

336 ESO: (MPG/ESO 2.2-m + WFI) (cr); Andy Lawrence, University of Edinburgh Institute for Astronomy: (bl) © Smithsonian Institution: (ca). 337 Courtesy of NASA/WMAP Science Team: (c); NRAO: Rudnick et al./NASA (crb); SPL: Max Planck Institute for Astrophysics/Volker Springel (tl).

338–339 Sloan Digital Sky Survey: (c). 339 2dF Galaxy Redshift Survey Team (www2.aao.gov. au/2dFGRS): (c); Alamy Images: Richard Wainscoat (cr). 340–341 NASA: 2MASS/T. Jarrett (IPAC/Caltech). 342–343 NASA: JPL. 344–345 Credner. 346 British Library, London: shelfmark: Harley 647, folio: f.13 (c); DK Images: courtesy of the National Maritime Musem, London/James Stevenson (br); courtesy of the National Maritime Museum, London/Tina Chambers (bl). 347 akg-images: Musée du Louvre, Paris (br); BAL: Private Collection,The Stapleton Collection (la, lb); British Library, London: shelfmark: Maps.C.10.c.10, folio: 5 (tr). 354 BAL: National Gallery of Art,Washington D.C., USA/Lauros/Giraudon (br); GPL: Damian Peach (c); Robin Scagell (t). 355 BAL: Palazzo Vecchio (Palazzo della Signoria) Florence, Italy (br); Credner: (tr); NOAO: Adam Block (cl). 356 Credner: (tr); GPL: Michael Stecker (tc); SPL: Harvard College Obs. (br). 357 Credner: (br); NOAO: (tcb); Hillary Matthis, N.A. Sharp (tcl); courtesy of Ian Ridpath: (cra). 358 Credner: (bl); Digital Library of Dutch Literature (www.dbnl.org): (br); GPL: Robin Scagell (tr); NOAO: Fred Calvert/Adam Block (cb). 359 Credner: (c, br); NOAO: Adam Block (cr). 360 NOAO: Gary White and Verlenne Monroe/Adam Block (tr); Jeff Cremer/Adam Block (br); Joe Jordan/ Adam Block (cr). 361 British Library, London: shelfmark: Or. 8210/S. 3326 (br); Credner: (c); GPL: Damian Peach (tc). 362 Credner: (br); NOAO: Elliot Gellam and Duke Creighton/Adam Block (bl); Jon and Bryan Rolfe/Adam Block (tc); N.A. Sharp (cb). 363 Corbis: The Stapleton Collection (tc); Credner: (br); GPL: Damian Peach (cr). 364 Credner: (tr); GPL: Eddie Guscott (crb); NOAO: Burt May/Adam Block (br). 365 akg-images: Hessisches Landesmuseum (bc); Credner: (br); NOAO: Adam Block (cl). 366 Credner: (br); GPL: Damian Peach (tc). 377 Corbis: Allinari Archives/Mauro Magliani (tr); GPL: Philip Perkins (cbr); NOAO: Adam Block, Jeff and Mick Stuffings, Brad Ehrhorn, Burt May, and Jennifer and Louis Goldring (br); Heidi Schweiker (ca). 368 Corbis: Archivo Iconografico, S.A. (br); Credner: (bl); NOAO: Adam Block (c); SPL: Tony Hallas (cl). 369 Credner: (ca, bc); NOAO: T.A. Rector (NRAO/ AUI/NSF and NOAO) and M. Hanna (br). 370 Corbis: Massimo Listri (tr); Credner: (cr); SPL: Jerry Lodriguss (br). 371 akg-images: (bl); Credner: (r); GPL: Robin Scagell (tc). 372 NOAO: Adam Block (bl); SPL: John Sanford (tc). 373 akg-images: © Sotheby’s (br); Credner: (t). 374 Credner: (b); NOAO: N.A. Sharp (trb); Sharon Kempton and Karen Brister/Adam Block (tc). 375 BAL: Private Collection,The Stapleton Collection (cra); Credner: (br); GPL: Robin Scagell (car); NOAO: Nigel Sharp, Mark Hanna (c). 376 Credner: (tc, br); GPL: Nik Szymanek/Ian King (car); NOAO: (cr). 377 Corbis: Arte and Immagini sr (bc); Credner: (bl); GPL: Damian Peach (cbr); NOAO: REU Program (cr). 378 Corbis: Archivo Iconografico, S.A. (tc); Credner: (br); NOAO: Adam Block (bl); Morris Wade/Adam Block (clb). 379 akg-images: Museum of Fine Arts Boston/Erich Lessing (br); Credner: (ca, bc). 380 Credner: (br); NOAO: Bill Schoening (bl); Hillary Matthis, REU Program (cl). 381 Corbis: Gianni Dagli Orti (br); Credner: (bl); GPL: Michael Stecker (cb); NOAO: N.A. Sharp,Vanessa Harley/REU Program (bc). 382 Credner: (tr, br); NOAO: N.A. Sharp, REU Program (ca); SPL: John Sanford (cb). 383 akgimages: Erich Lessing (tr); Credner: (br); GPL: Robin Scagell (ca, cl). 384 Corbis: Bettmann (br); Credner: (bl); GPL: Nik Szymanek (cl); Robin Scagell (c). 385 Credner: (tr, br); GPL: Damian Peach (tc); courtesy of Osservatorio Astronomico di Palermo Giuseppe S.Vaiana: (cl). 386 Corbis: Richard T. Nowitz (br); Credner: (tr); NOAO: (bc). 387 Credner: (b); courtesy of William McLaughlin: (clb, crb). 388 BAL: Palais du Luxembourg, Paris, France/ Giraudon (crb); Credner: (c); GPL: Robin Scagell (tr); NOAO: Todd Boroson (br). 399 Corbis: The Stapleton Collection (br); Credner: (bl); NOAO: Francois and Shelley Pelletier (tc). 390 Credner: (r); GPL: Duncan Radbourne (cl); The Picture Desk: The Art Archive/Bodleian Library, Oxford (bl). 391 GPL: Michael Stecker (tr, br); NOAO: Jim Rada/Adam Block (tc). 392 Credner: (cr, br); GPL: Pedro Rè (tc); The Picture Desk: The Art Archive/Private Collection/ Marc Charmet (c). 393 Credner: (bl); GPL: Michael

Stecker (cr); NOAO: Michael Gariepy/Adam Block (tr). 394 Corbis: Todd Gipstein (tc); NOAO: Adam Block (cb); Allan Cook/Adam Block (bl). 395 Credner: (t). 396 Daniel Verschatse (www.astrosurf.com): (cla); Credner: (cb); GPL: Gordon Garradd (bcr);Yoji Hirose (cra). 397 Credner: (ca, br); Mary Evans Picture Library: (cra); NOAO: Bob and Bill Twardy/Adam Block (c). 398 Corbis: Araldo de Luca (cr); GPL: (crb, bl). 399 BAL: Bibliothèque Nationale, Paris, France/Archives Charmet (bl); Credner: (br); GPL: Gordon Garradd (ca). 400 GPL: Michael Stecker (tr, clb); NOAO: Todd Boroson (bl). 401 Credner: (t); NOAO: (bl). 402 Corbis: Archivo Iconografico, S.A. (br); Credner: (bl); SPL: Rev. Ronald Royer (tr). 403 Corbis: Andrew Cowin (cr); Credner: (ca, bc); GPL: Pedro Rè (tcl). 404 Credner: (cra, bc); NOAO: T.A Rector (br). 405 AAO: Royal Obs. Edinburgh. Photograph from UK Schmidt plates by David Malin (tc); Credner: (cl, br); ESO: (VLT UT1 + FORS1) (trb). 406 Credner: (bl); GPL: Gordon Garradd (tr); NOAO: Nicole Bies and Esidro Hernandez/Adam Block (br). 407 BAL: Musée Conde, Chantilly, France/Giraudon (br); Credner: (bl); GPL: DSS (cr); NOAO: Adam Block (c). 408 akg-images: Museo Capitular de la Catedral, Gerona/Erich Lessing (c); Credner: (tr, bc). 409 Credner: (bl); GPL: Michael Stecker (bcr); Pedro Rè (cl); NOAO: (crb). 410 Credner: (tr); GPL: Chris Pickering (br); Gordon Garradd (tc); The Picture Desk: The Art Archive/ Museo Civico Padua/Dagli Orti (bl). 411 Credner: (r); GPL: Robin Scagell (cb); NOAO: (bl). 412 Corbis: Bettmann (bcr); Credner: (cr); GPL: Yoji Hirose (cbl); NOAO: (bl). 413 Credner: (tr, bc); GPL: Gordon Garradd (tc). 414 Credner: (tr, br); GPL: Gordon Garradd (tc). 415 akg-images: Pergamon Museum, Berlin/Erich Lessing (cl); Credner: (tr, br); GPL: Gordon Garradd (c). 416 BAL: Cheltenham Art Gallery and Museums, Gloucestershire, UK (cr); Credner: (tr, bl). 417 akg-images: Coll.Archiv f. Kunst and Geschichte (crb); Credner: (tr, bc). 418 Credner: (br); GPL: Chris Livingstone (tcr); Michael Stecker (ca). 419 Credner: (tr, cb); GPL: Gordon Garradd (bcl). 420 Credner: (tc, br); ESO: Jean-Luc Beuzit,AnneMarie Lagrange (Observatoire de Grenoble, France), and David Mouillet (Observatoire de Paris-Meudon, France) (c). 421 BAL: © The Trustees of the Chester Beatty Library, Dublin (bl); Credner: (br); GPL: Chris Livingstone (tr); NOAO: Marcelo Bass/CTIO (tc). 422 Alamy Images: Chris Cameron (bcr); Credner: (tr, cb); SPL: (br). 423 Credner: (tr, br). 424 Credner: (bl); GPL: Gordon Garradd (c); Volker

Wendel and Bernd Flach-Wilken (www. spiegelteam.de): (cra). 425 Alamy Images: Adam van Bunnens (tr); Credner: (b); DK Images: Courtesy of the Science Museum, London/Dave King (crb). 426–427 GPL: Juan Carlos Casado. 429 DK Images: (tr). 430 GPL: Robin Scagell (cr). 431 GPL: Robin Scagell (tr); NOAO: Ryan Steinberg and family (tc). 436 DMI: Akira Fujii (cra). 437 Credner: (tr). 442 Corbis: Roger Ressmeyer (cra). 443 GPL: Gordon Garradd (tl). 448 Credner: (cra). 449 GPL: Yoji Hirose (cra); NOAO: (tl). 454 Credner: (cra). 455 DMI: Akira Fujii (cra). 460 Alamy Images: Pixonnet.com (cra). 461 DMI: Akira Fujii (tr). 466 DMI: Akira Fujii (cr). 467 DMI: Akira Fujii (tl). 472 Corbis: Reuters/Ali Jarekji (bl). 473 Credner: (tr); NOAO: Svend and Carl Freytag/Adam Block (ca). 478 Alamy Images: Gondwana Photo Art (bc). 479 GPL: Chris Livingstone (tl). 484 GPL: Yoji Hirose (br). 485 GPL: Robin Scagell (cla). 490 Credner: (tr). 491 GPL: Robin Scagell (tr). 496 Credner: (br). 497 GPL: Yoji Hirose (tr).

ENDPAPERS NOAO: Nathan Smith, Univ. of Minnesota. JACKET IMAGES Front: Corbis: Tony Hallas/Science Faction ca, STScI / NASA.

All other images © Dorling Kindersley For further information see: www.dkimages.com